smart street lighting initiative nama
TRANSCRIPT
Smart Street lighting Initiative
NAMA
Implementation Plan
I
Preface
In response to climate change the Government of Indonesia has established a national GHG mitigation
policy framework, which is detailed in the Presidential Regulation No. 61 – the National Action Plan for
GHG emission reduction (Rencana Aksi Nasional Penurunan Emisi Gas Rumah Kaca, RAN-GRK) on
20th of September 2011. RAN-GRK is regarded as the underlying policy for the development and
implementation of Nationally Appropriate Mitigation Actions (NAMAs). NAMAs shall support the further
implementation of the RAN-GRK with unilateral means (to support the 26% emission reduction target)
and with international support (to support emission reductions up to 41%). At the same time they shall
support Indonesia’s development goals.
Energy efficiency has been one of the main policies of the Government of Indonesia to develop more
sustainable and environmentally friendly national energy. Along with renewable energy development,
energy efficiency is the tool to move from dependency on fossil-based energy with the target of
elasticity less than 1 in 2025 and reducing energy intensity 1% per year. Economic growth, nourished
by high rates of fossil fuel use, has shifted the vastly growing energy sector alongside deforestation
and land-use changes at the center of climate policy and action. Herein, the Ministry of Energy and
Mineral Resources (MEMR) pursues an integrated NAMA approach consisting of measures on the
production side (maximize renewable energy utilization) and the consumption side (application of
energy efficient technologies) in various sub-sectors. This approach builds upon existing energy
policies and aims at gradually lowering GHG emissions in the energy sector’s development path.
The Smart Street Lighting Initiative (SSLI) NAMA constitutes one important element in Indonesia’s
integrated energy NAMA approach. It introduces and promotes efficient street lighting technologies in
a large scale of implementation, combined with the necessary capacity building measures related to
regulations, performance and safety standards, installation and maintenance, monitoring and
awareness raising. Its Impacts can be manifold: The application of more efficient street lighting
technologies leads to cost, energy and GHG reduction as well as increased safety in public spaces.
The SSLI NAMA implementation plan describes the necessary measures to be taken within this NAMA
in order to significantly improve Indonesia’s street lighting systems in urban areas up to 2020. The SSLI
NAMA implementation plan has been developed in a partnership with the German government. The
MEMR gratefully acknowledges the support of the GIZ Policy Advice for Environment and Climate
Change (PAKLIM) program in developing this NAMA concept and is looking forward to cooperate within
future implementation.
Maritje Hutapea
Director for Energy Conservation
Directorate General of Electricity and Energy Utilization Ministry of Energy and Mineral Resources
II
Author team
Perspectives GmbH: Axel Michaelowa
Killian Wentrup
Michel Köhler
Stefan Wehner
ICLEI: Emani Kumar
Anandhan Subramaniyam
Ashish Verma
GIZ: Philipp Munzinger
Endot Purba
Trita Katriana
Jakarta, December 2013
III
Contents
1. Executive summary ....................................................................... 1
2. Introduction ................................................................................ 6
3. Context ...................................................................................... 6
3.1. The Smart Street Lighting NAMA in the context of Indonesia’s climate policy 6
3.2. The technology context .................................................................. 9
Light Emitting Diodes (LEDs) ................................................................................................. 9
Magnetic Induction Lighting ............................................................................................... 11
4. Smart street lighting NAMA implementation plan ................................... 15
4.1. Institutional framework .................................................................. 15
4.1.1 Existing institutional framework ................................................................................ 15
4.1.2 Challenges for the institutional framework................................................................. 18
Coordination of multiple agencies and actors ..................................................................... 18
Addressing the incentive structure regarding billing and metering ...................................... 19
4.1.3 Establishment of technical support unit (TSU) ............................................................ 20
4.2. Policy and regulations .................................................................... 24
4.2.1 Assessment of existing pricing policies and regulations ............................................... 24
4.2.2 Available options for reforming pricing policies and regulations.................................. 28
4.2.3 Possible next steps .................................................................................................... 32
4.3. Baseline data ............................................................................... 33
4.3.1 Availability of national data on street lighting energy consumption ............................ 33
4.3.2 Identification of a suitable baseline determination approach .................................. 34
4.3.3 Key baseline parameters ........................................................................................ 34
4.3.4 Recommendations ..................................................................................................... 36
4.4. Performance and safety standardisation for LEDs .................................. 37
4.4.1 Background ............................................................................................................... 37
4.4.2 Existing Standards for street lighting in Indonesia ....................................................... 37
4.4.3 Road Classification & Standards for Illumination ........................................................ 39
4.4.4. International experience in defining LED street lighting standards ............................. 41
4.4.5. Developing standards for LED lighting in Indonesia .................................................... 43
4.4.6 Lessons from international standards setting process ................................................. 46
4.4.7. Enhancing technical capacity of institutions developing standards on performance and
safety ................................................................................................................................ 47
4.4.8. Barriers/challenges ................................................................................................... 48
IV
4.4.9. Recommendations .................................................................................................... 48
4.5. Financing options for efficient street lighting ....................................... 49
4.5.1 Overview of resource needs for the SSLI NAMA. ......................................................... 49
4.5.2 Methodological approach for calculation of cash flows for baseline and project scenario
.......................................................................................................................................... 53
4.5.3 Identification of funding sources ................................................................................ 55
4.5.4 Assessment of financing options ................................................................................ 62
4.5.5 Case studies demonstrating the use of different financing pathways ........................... 65
4.5.6 Financing roadmap utilising a mix of sources .............................................................. 70
4.5.7 Challenges to be overcome in the financing roadmap ................................................. 77
4.5.8 Recommendations ..................................................................................................... 78
4.6. Estimated emissions reductions and abatement costs ............................. 79
4.6.1 Estimating emissions reductions against the baseline ................................................. 79
4.6.2 Approach based on CDM methodology AMS-II.L ......................................................... 80
4.6.3 Results of emissions reduction estimation .................................................................. 83
4.6.4 Estimated cost of abatement ..................................................................................... 85
4.7. Installation and maintenance ........................................................... 85
4.8.1 MRV of emission reductions ...................................................................................... 94
4.8.2 NAMA MRV requirements ......................................................................................... 94
4.8.3 Options for the SSLI NAMA MRV framework .............................................................. 97
4.8.4 MRV of co-benefits .................................................................................................. 103
4.8.5 Institutional responsibilities for MRV .................................................................... 104
4.8.6 MRV of financial flows .......................................................................................... 107
4.8.7 Recommendations ............................................................................................... 107
4.9. Raising awareness amongst stakeholders ............................................. 108
5. Summary of recommendations ......................................................... 113
6. References: ................................................................................ 118
V
Index of figures
Figure 1: Coordination of national and provincial climate action ............................................................ 7
Figure 2: Examples of LEDs and LED modules ................................................................................... 10
Figure 3: Induction streetlight ............................................................................................................... 12
Figure 4: Organizational set-up of Technical Support Unit (TSU) within MEMR ................................. 24
Figure 5: Cost recovery and payment mechanism for street lighting electricity ................................... 27
Figure 6: Standard setting process of BSN .......................................................................................... 44
Figure 7: Standard setting process of BIS ............................................................................................ 46
Figure 8: Phases and scenarios for efficient street lighting implementation ........................................ 51
Figure 9: Estimated number of replaced lamps under the two pathways ............................................ 53
Figure 10: Map of Java with Yogyakarta highlighted .......................................................................... 65
Figure 11: Accumulated cash flows for the baseline and the efficient lighting scenario (including PIP
loans) .................................................................................................................................................... 67
Figure 12: Map of Java with Probolinggo highlighted ......................................................................... 68
Figure 13: Development of the net cash flows for the baseline and the efficient lighting scenario
(including PIP loans) ............................................................................................................................. 70
Figure 14: Investment roll-out under the conservative pathway ........................................................... 73
Figure 15: Discounted net cash flow under the conservative pathway ................................................ 73
Figure 16: Investment roll-out ambitious pathway ................................................................................ 75
Figure 17: Discounted net cash flow under the ambitious pathway ..................................................... 76
Figure 18: Discounted net cash flow under the ambitious pathway with additional 11.5 million USD
grant ...................................................................................................................................................... 76
Figure 19 Comparison of investment needs in the two pathways ........................................................ 77
Figure 20: CO2 reductions under the conservative and ambitious pathway ........................................ 84
Figure 21: Institutional set-up for MRV ............................................................................................... 105
Figure 22: NAMA database for MRV .................................................................................................. 106
Figure 23: Tracking of financial flows under the NAMA ..................................................................... 107
Index of tables
Table 1: Institutions and Actors Involved in Implementing the SSLI NAMA ........................................... 2
Table 2: Summary of SSLI NAMA Implementation Pathways ............................................................... 3
Table 3: Overview of street lighting in provincial RAD-GRK climate action plans ................................. 8
Table 4: Fixture technology options for street lighting .......................................................................... 14
Table 5: Institutional framework for the SSL NAMA ............................................................................. 15
Table 6: Outline of SSL NAMA Technical Support Unit (TSU) within MEMR ...................................... 21
Table 7: Effective Power Rating of street lighting lamps ...................................................................... 25
VI
Table 8: Overview of street lighting taxes for selected cities in Indonesia ........................................... 27
Table 9: Metering rates in Indonesian cities being targeted for the SSL NAMA .................................. 31
Table 10: Contribution of street lighting to local government GHG emissions ..................................... 33
Table 11: Technical parameters for baseline estimation ...................................................................... 35
Table 12: Financial parameters for baseline estimation ....................................................................... 35
Table 13: Grid Emission Factors relevant for cities targeted under the SSLI NAMA ........................... 36
Table 14: Road classification and street lighting specifications in Indonesia ....................................... 39
Table 15: Type of roads and levels of illumination based on Bureau of Indian Standards .................. 40
Table 16: Indicative product specification for LED lighting .................................................................. 42
Table 17: Technical parameters ........................................................................................................... 50
Table 18: Financial parameters ............................................................................................................ 50
Table 19: Overview of SSL NAMA Implementation Phases and Scenarios for analysis ..................... 51
Table 20: Cumulative number of lamps and resource needs for the two pathways ............................ 52
Table 21: Parameters included in financial analysis of SSL NAMA ..................................................... 53
Table 22: Qualitative assessment of financing options ........................................................................ 63
Table 23: Socio-economic and street lighting specific parameters of Yogyakarta (annually, 2008 data)
.............................................................................................................................................................. 66
Table 24: Socio-economic and street lighting specific parameters of Probolinggo (annually, 2008 data)
.............................................................................................................................................................. 69
Table 25: Summary of financing pathway modelling ............................................................................ 77
Table 26: Key data required for emission reduction calculations ......................................................... 81
Table 27: Summary of city level data used for emissions reduction estimation................................... 82
Table 28: Summary of results from emissions reduction estimation for both pathways ...................... 84
Table 29: Specifications for street lighting poles .................................................................................. 87
Table 30: Distance between poles (in meters) based on typical lighting distribution and classification of
lights (Lantern A) .................................................................................................................................. 88
Table 31: Distance between poles (in meters) based on typical lighting distribution and classification of
lights (Lantern B) .................................................................................................................................. 89
Table 32: Lamp Technologies .............................................................................................................. 90
Table 33: Overview of training programmes ........................................................................................ 93
Table 34: UNFCCC MRV requirements for NAMAs ............................................................................. 95
Table 35: Comparison of likely MRV elements for different NAMA types ............................................ 97
Table 36: Minimum sample size in dependency of the confidence interval ....................................... 102
Table 37: Criteria and measurable indicators for co-benefits ............................................................. 103
Table 38: Method for obtaining parameter values under MRV framework ........................................ 105
Table 39: Barriers associated with uptake of energy efficiency measures and policies .................... 108
Table 40: Target groups for training and focus areas ........................................................................ 111
VII
Index of acronyms
ADB Asian Development Bank
AILKI Association of Lighting and Electrical Industries
ANSI American National Standards Institute
ASTM American Society for Testing and Materials
BAPPENAS Ministry of National Development Planning
BE Baseline emissions
BEE Indian National Energy Efficiency Agency
BIS Bureau of Indian Standards
BL Baseline
BLH Local Environment Agency (Badan Lingkungan Hidup)
BMU German Federal Ministry for the Environment, Nature Conservation and Nuclear
Safety
BOCM Japanese Bilateral Offsetting Credit Mechanism
BPK Supreme Audit Agency
BSN National Standardisation Agency of Indonesia
BURs Biennial update reports
CAPEX Capital Expenditure
cd candela
CDM Clean Development Mechanism
CERs Certified Emission Reductions
CFL Compact fluorescent lamp
CIE Commission internationale de l’éclairage
CMH Ceramic Metal Halide
COP Conference of the Parties
CRI Colour rendering index
DAK Special Allocation Fund
DGEEU Directorate General of Electricity
DKP Agency for Hygiene and Landscape Gardening (Dinas Kebersihan dan Pertamanan)
DNA Designated National Authority
DNPI National Council on Climate Change
DO Delivery Organisation
DOE Designated Operational Entities
DPU Local Public Works Agency (Dinas Pekerjaan Umum)
EB Executive Board
EE Energy efficiency
EBTKE Directorate General of New/Renewable Energy and Energy Conservation
ERs Emissions Reductions
VIII
ES Electrical savings
ESCO Energy Services Company
ESDM Centre for Data and Information on Energy and Mineral Resources
EU ETS European Union Emissions Trading Scheme
EUR Euro
FDI Foreign Direct Investment
FTL Fluorescent Tubular Lamp
g1 Emin/Emax
GDP Gross Domestic Product
GEF Grid emission factor
GHGs Greenhouse Gases
GIZ German Society for International Cooperation
GoI Government of Indonesia
GWh Gigawatt hours
HID High-intensity discharge
HPS High-Pressure-Sodium
HPSV High Pressure Sodium Vapour
ICA International Consultation and Analysis
ICLEI International Council for Local Environmental Initiatives
ICCTF Indonesia Climate Change Trust Fund
IDR Indonesian Rupiah
IEC International Electrotechnical Commission
IES Illumination Engineering Society
INR Indian Rupee
IPP Independent Power Producer
IRR Internal Rate of Return
ISO International Organization for Standardization
JAMALI Jakarta Madura Bali Grid
JIS Japan Industrial Standard
kW Kilowatt
kWh Kilowatt hours
LED Light-emitting diode
lm lumens
MASTAN Standardisation Society of Indonesia
MBF/U Mercury vapor lamps
MoE Ministry of Environment
MoF Ministry of Finance
MEMR Ministry for Energy and Mineral Resources
MER Monitoring, Evaluation and Reporting
MFI Multilateral Financial Institutions
IX
MH Metal Halide
MoI Ministry of Industry
MoT Ministry of Transport
MPW Ministry of Public Works
MRV Measurement, Reporting and Verification
Mt CO2e Million tonnes of Carbon Dioxide Equivalent
MW Megawatt
MWh Megawatt hours
NAI Non-Annex I parties
NAMA Nationally Appropriate Mitigation Action
NES Net electricity savings
NGO Non-governmental organisation
NMM New Market Mechanism
NPV Net Present Value
O&M Operations and maintenance
Oi Annual operating hours
ODA Official Development Assistance
OWG Other Working Groups
P Project
PAKLIM Policy Advice for Environment and Climate Change
PAS Performance and Safety
PDD Project Design Document
PE Programme emissions
PIP Indonesian Investment Agency
PJU Local government units responsible for street lighting
PLN National Electricity Utility
PNPS Planning of National Program for Standard Development
PPP Public-private-partnerships
RAD-GRK Provincial action plans
RAN-GRK National Action Plan on Emission Reduction
R&D Research and Development
RSNI Standard Draft
SBSTA Subsidiary Body for Scientific and Technological Advice
SC Steering Committees
SN Serial number
SNI Standar Nasional Indonesia, Indonesian National Standards
SOF System Outage Factor
SON High pressure sodium lamps
SOX Low pressure sodium lamps
SSC Small scale
X
SSL Smart Street lighting
SSLI Smart Street Lighting Initiative
TA technical assistance
T&D Transmission and Distribution
TBT Technical Barriers to Trade
tCO2-e Tonnes of Carbon Dioxide Equivalent
TDL Transmission and distribution losses
TJ Glare Limitation
ToT Training of Trainers programs
TSU Technical Support Unit
ULBs Urban Local Bodies
UN United Nations
UNFCCC United Nations Framework Convention on Climate Change
US United States of America
USAID U.S. Agency for International Development
USD US Dollar
UU National law
VA Effective power
VD Lmin/Lmax
VI Lmin/Laverage
WTO World Trade Organization
WIPP Waste Isolation Pilot Plant
1
1. Executive summary
In 2009, the Indonesian President Susilo Bambang Yudhoyono pledged to reduce the country’s
greenhouse gas (GHG) emissions by 26% compared with business as usual (BAU) by 2020 and up to
41% below BAU with international support. This was translated into a National Action Plan on Emission
Reduction, known as the ‘RAN-GRK’, in 2011, which calls for actions across all major sectors of the
economy. Actions undertaken to meet this target are detailed in provincial action plans or ‘RAD-GRK’.
Indonesia’s coal-dominated power supply is a major source of GHG emissions. Emissions from the
generation of electricity have increased in line with the country’s strong economic performance in recent
years and this trend is set to continue with electricity demand growth projected at around 9% per annum,
resulting in the need for over 50 GW of new generating capacity by 2025. Energy efficiency measures
in the cities and urbanised areas could thus make an important contribution to meeting Indonesia’s GHG
emissions reduction targets.
Some cities, including Yogyakarta and Makassar, have experience with the introduction of energy-
efficient street lighting, including Light Emitting Diode (LED) lamps. LEDs have been improving steadily
since the 1960s and although the upfront costs are still 2-4 times that of most conventional lamps, the
energy consumed is half of an equivalent conventional lamp or less and LEDs last longer. The limited
experience to date in Indonesian cities shows the significant energy savings that can be achieved by
LEDs compared with conventional lamps - up to 60% in optimal conditions. Other efficient lighting
technologies such as induction lamps and approaches such as dimming and use of movement sensors
can also result in significant energy savings and are slowly being tested by Indonesian cities. The uptake
of such measures results in associated GHG emissions and cost savings as well as other co-benefits
including enhanced public amenity, the creation of job opportunities, and improved safety due to better
illumination of roads at night. The perception of improved safety due to better lighting in public spaces
could increase the mobility and freedom of women in particular to use public transportation, to extend
working hours, and to participate in community life. Thus, a gender-sensitive approach to improved
street lighting could maximise the benefits (improving livelihoods) for various groups of society in urban
areas.
Due to a range of challenges, however, efficient street lighting has not been a priority for Indonesian
cities to date. Common problems experienced by the local government units responsible for street
lighting, known as ‘PJUs’, include:
A lack of adequate data on the number and type of installed lamps, due principally to the high
number of illegal connections and the low level of electricity metering for street lighting.
The standard practice of being billed by PLN1 on a lump-sum basis, which tends to over-
estimate consumption and reduces the incentive to implement more efficient street lighting.
1 National Electricity Utility (Perusahaan Listrik Negara – PLN)
2
Many PJUs are constrained in their budgets and local governments are typically unable or
unwilling to increase the street lighting taxes further to raise additional revenues.
Nationally Appropriate Mitigation Actions (NAMAs) are voluntary emission reduction measures initiated
by developing countries under the UNFCCC2 and are typically aligned with national policy objectives. If
conceptualised as a NAMA, a “Smart Street Lighting Initiative” (SSLI) aimed at driving the introduction
of energy-efficient street lighting technologies in cities and provinces of Indonesia could contribute to
the RAN-GRK objectives. The SSLI NAMA would involve several government institutions at the national
level, provincial and municipal governments, as well as the private sector. The NAMA would be open to
a wide range of efficient and smart technologies, not just limited to LEDs. However, the majority of the
analysis in this report has focused on LEDs for sake of simplicity.
The NAMA will logically be coordinated by the Ministry for Energy and Mineral Resources (MEMR),
which is the agency responsible for setting energy efficiency policy. In addition, the following institutions
are identified as playing a particularly critical role in the implementation of the SSLI NAMA (see Table 1
below).
Table 1: Institutions and Actors Involved in Implementing the SSLI NAMA
Institution / actor Role
BAPPENAS Responsible for overall coordination of Indonesia’s NAMAs;
Responsible for overseeing the Indonesia Climate Change Trust
Fund (ICCTF), a key channel for delivering finance for investment
in smart street lighting technologies
The Indonesian Investment
Agency (PIP) at the Ministry
of Finance
Sits within the Ministry of Finance (MoF) and would be responsible
for providing concessional loans to the participating cities, which is
another key element of the financing package
Ministry of Industry (MoI) Responsible for setting standards of lighting products, and would
do so for LED lamps as no national standard for LED street
lighting products currently exists
Ministry of Environment
(MoE)
Responsible for keeping track of measured GHG emission
National Standardisation
Agency of Indonesia
Responsible for facilitation and/or endorsement of national
standard (SNI) for LED street light
Municipal level PJUs Responsible for the management of street lighting infrastructure in
Indonesian cities, including installation and maintenance of
infrastructure
Provincial level governments Responsible for street lighting on roads outside of cities
PLN The national electricity utility, which is responsible for installation of
metering, collection of metered data, collecting the street lighting
tax and billing cities for their consumption
Private sector Includes lighting suppliers as well as Energy Services Companies
(ESCOs)
2 United Nations Framework Convention on Climate Change (UNFCCC)
3
With such a complex institutional environment, the effective coordination of the multiple actors at the
national, provincial and municipal level is a key success factor.
MEMR could access international NAMA support funding with both technical and capital cost
components. Firstly, this funding could help set up a Technical Support Unit (TSU) which would be
responsible for delivering the Technical Assistance (TA) component to the cities involved in the SSLI
NAMA. Secondly, international NAMA support could provide finance to kick-start the required capital
investment over the intended time frame of 2014-2020. These international funds should be leveraged
with additional sources of domestic finance, both private and public.
Specifically, the finance package outlined in this report envisages international NAMA support via initial
grants of USD 19m, including a target capital component in the order of USD 11.5m and a TA component
of around USD 7.5m. The capital investment support should be channelled through the existing financing
facility of the ICCTF energy window, while the TA could be managed by GIZ. Domestic concessional
loans should be made available to cities and provinces via PIP using the existing institutional framework
and financing instruments but with streamlined procedures for cities to access funds. Further, the private
sector must be enabled to provide finance, including via the ESCO model. Additional forms of finance
will also be required for the SSLI NAMA to become truly transformational by 2020. It is thus
recommended to seek additional international and domestic support with a second grant of USD 11.5m
targeted to complement the initial NAMA grant.
Based on the envisaged financing package, the implementation of the SSLI NAMA has been assessed
under two different levels of ambition, or pathways. The results that can be achieved have been
estimated and are outlined in Table 2 below.
Table 2: Summary of SSLI NAMA Implementation Pathways
Implementation Phases Conservative Pathway
Incremental Cumulative
Ambitious Pathway
Incremental Cumulative
I: Demonstration phase
Jan 2014 - Jun 2015
2 cities
2 cities
4 cities
4 cities
II: Scaling-up phase
Jul 2015 – Dec 2016
2 new cities
join
4 cities 8 new cities join
12 cities
III: Transformation phase
Jan 2017 – Dec 2019
5 new cities
join
9 cities 10 new cities join
22 cities
Total capital cost USD 155m USD 420m
NPV to 2024
(8% discount rate)
USD 3m USD -7m without any additional grants
USD 15m with an additional grant of
USD 11.5m
Emissions reductions 210,000 t CO2-e to 2020 640,000 t CO2-e to 2020
Approximately 1.5 Mt by 2024
4
Cost of abatement
(8% discount rate)
-4 EUR/t CO2-e 2 EUR/t CO2 or -8 EUR/t CO2 with an
additional grant of USD 11.5m
The analysis highlights that in order achieve significant emissions reductions a rapid scaling up of the
SSLI will need to be achieved. Based on the estimates in this report, around 22 small, medium and large
cities would have to join by 2020 if GHG emissions are to be reduced by 1.5 Mt by 2024 (cumulatively).
To achieve such results, a number of barriers will need to be overcome. In summary, the SSLI NAMA
will involve the following activities:
Help local governments deal with technical issues, provide staff training programmes and support
them with implementation of the Monitoring, Reporting and Verification (MRV) plan.
Help ensure that PLN’s billing approach can account for installed efficient lamps more smoothly, so
that cities are able to reduce their expenditure accordingly.
Help local government to overcome the incremental cost of switching to LEDs/other smart lighting
technologies through the provision of financial assistance (loans and grants).
Help local government access different sources of finance involved in the NAMA by smoothing
procedures and requirements and providing hands-on support for interested cities.
Undertake awareness-raising efforts to attract new cities/provinces to join the NAMA over time.
Develop training programmes to improve the skills of workers involved in installation/maintenance.
More widespread reform of Indonesia’s electricity pricing and regulations should also be pursued in the
context of its national energy policy. However, it is recognised that it may not be feasible for such reforms
to be implemented in the time frame intended to enable a quick start for SSLI NAMA.
The current lack of national performance standards for LED products is a potential risk to the successful
implementation of the SSLI NAMA. If sub-standard products are allowed to enter the market this will
negatively impact on perceptions of the quality of LEDs and slow down the uptake of the technology.
The SSLI should also be open and flexible, allowing potentially for other lighting technologies such as
induction lamps to be adopted where cities choose to pursue these. While the development of a national
standard for LED products is planned, it could take 1-2 years. Therefore an interim solution may be
needed. Consensus is required from the relevant ministries and government agencies involved in
standards if Indonesia were to adopt a standard based on the available international standards
established by the IEC and IES3 and/or other Asian countries such as India.
Installation and maintenance practices are not consistent across Indonesian cities due to the lack of
awareness of the national street lighting standards and the absence of design-based street lighting
3 International Electrotechnical Commission (IEC), Illuminating Engineering Society (IES)
5
systems. This results in the adoption of inappropriate technologies, which do not provide the necessary
level of service to citizens and is thus closely linked to the high level of illegal connections.
MRV of the SSLI NAMA outcomes is an important element of the SSLI from both a national policy
perspective and an international perspective under the UNFCCC framework. The GHG reductions
resulting from the lighting replacement is the key outcome to be monitored, reported and verified, but
other co-benefits could also be included in the MRV framework. For monitoring GHG reductions, an
approach for the SSLI NAMA can be developed based on the approved CDM methodology AMS.II.L
Demand-side activities for efficient outdoor and street lighting technologies. The approach in AMS.II.L
uses sampling of lamp operating hours and calculated energy savings based on lamp specifications and
the number of replaced lamps. This makes it possible for cities that have not yet implemented
widespread metering to join the SSLI. Cities that are already advanced in their metering installation
programme should utilise metered data for emissions monitoring as this will be more accurate.
Greater coverage of electricity metering is a key success factor that will address the lack of reliable data
and free up local government financial resources. Of the cities considered in this report, only Yogyakarta,
Makassar and Cimahi have achieved full or near-full metering coverage. Other cities could be supported
by the national government to overcome the up-front costs of metering if it is recognised as a national
priority. In the meantime, baseline estimation should be done at the city/province level and can be
estimated ex-ante and then adjusted ex-post. A certain minimum level of data quality/metering is
recommended for cities joining the SSLI NAMA to ensure reliability.
On-going and continuous awareness-raising efforts will be required if the SSLI NAMA is to be effectively
implemented, achieve the intended scale foreseen in this report, and to ultimately reduce GHG
emissions. The TSU will play a critical role in this respect.
6
2. Introduction
This report outlines the strategy for the implementation of a Nationally Appropriate Mitigation Action
(NAMA) in Indonesia involving the installation of efficient lamps in place conventional lamps currently
used for street lighting. The activities that are to be undertaken as part of implementing this NAMA,
referred to hereafter as the Smart Street lighting Initiative (SSLI) NAMA, will be carried out by various
actors at the national and local government level as well as the private sector. The resources required
for enabling the NAMA to go ahead are to come from the combination of both domestic Indonesian
resources and international climate finance.
The report was commissioned by GIZ and is published by the Ministry for Energy and Mineral Resources
(MEMR), which will act as the Government agency with primary responsibility for coordinating the
implementation of the SSL NAMA. The report was prepared by a team of consultants from Perspectives
GmbH, ICLEI and the GIZ PAKLIM program.
3. Context
3.1. The Smart Street Lighting NAMA in the context of Indonesia’s climate policy
The energy sector is the second largest contributor to Indonesia’s greenhouse gas emissions, which
are otherwise mainly dominated by emissions from deforestation and land use change; in 2005 energy
sector emissions accounted for around 20% of total emissions when land sector emissions are included,
or around 56% without including land sector emissions (Second National Communication to the
UNFCCC in: Government of Indonesia, 2010). Energy sector emissions totalled around 370 Mt CO2-e
in 2005, with emissions from electricity generation being the major contributor. Strong economic
performance and an abundance of coal for power generation contributed to a growth of over 30% in
energy sector emissions between 2000 and 2005.
Annual electricity demand in Indonesia is growing at around 9% and the national, state-owned, electricity
utility PLN forecasts that the total electricity generation capacity needs to be increased from around 30
GW to around 83 GW by 2025 to meet this growth in demand (Differ Group, 2012). The energy sector
and the management of demand growth is therefore very relevant in the Indonesian climate and energy
policy context.
Due to Indonesia’s far-reaching decentralization, its climate policy is multi-layered and complex4. In
2009, President Susilo Bambang Yudhoyono made a pledge for Indonesia to reduce its emissions by
26%, and up to 41%, with international support, putting Indonesia at the forefront of countries willing to
4 For a history of the development of Indonesia’s climate policy see Purnomo, A.: Evolution of Indonesia’s Climate Change Policy;
From Bali to Durban. Jakarta, 2013
7
pledge ambitious abatement targets internationally. After the Copenhagen climate change conference,
the 26% reduction was translated into a National Action Plan on Emission Reduction (“RAN-GRK”)
which details Indonesia’s submission to the UNFCCC into national and sectoral planning on how, when,
and where the reduction will take place (Purnomo, 2013). A number of challenges remain, however,
including the definition of a national baseline, allocation of the target to sectors, and implementation of
a detailed monitoring, reporting and verification (MRV) framework. NAMAs can help contribute towards
the achievement of Indonesia’s abatement target, but exactly how this is to be done is still being defined.
The National Action Plan was specified by presidential decree (Perpres) 61/2011, which also defined
the role of Provincial Action Plans (“RAD-GRK”). While the National Action Plan, RAN-GRK, is the key
policy framework for the achievement of the national GHG emission reduction goals, the actions
themselves often need to be taken at the local level, which is specified in the RAD-GRKs, which are to
be developed by each province. So far, 32 of the 33 provinces have published their RAD-GRK action
plans. In some cases, the actions that need to be implemented also require the direct participation of
municipal governments, for example in the area of street lighting energy efficiency. The achievement of
Indonesia’s greenhouse gas abatement goals thus potentially involves three layers of government -
national, provincial and municipal - each of which has a separate government, with its own legislative
and budgetary procedures, but must work together effectively to achieve the intended outcomes.
Figure 1: Coordination of national and provincial climate action
Source: BAPPENAS (2012)
To date, only three provincial governments have explicitly included actions involving energy efficiency
improvements for street lighting in their RAD-GRK climate plans, while an additional 4 have included
non-specified lighting replacement activities, with two of these identifying Light Emitting Diode (LED)
technologies. In addition, a number of Indonesian cities are starting to develop GHG mitigation action
plans; for example, in 2012 Yogyakarta city released a GHG inventory and action plan, prepared by
ICLEI with support from USAID (U.S. Agency for International Development).
8
Table 3: Overview of street lighting in provincial RAD-GRK climate action plans
Province Explicitly mentions energy efficient
lamps for street lighting
Includes energy efficient lamps but
not explicitly for street lighting
DKI Jakarta
Jawa Tengah
Gorontalo
DI Yogyakarta (LED)
Sulawesi Utara (LED)
Kalimantan Barat
Sulawesi Tenggara
Source: Analysis by GIZ in 2013
The primary benefit of implementing SSL for Indonesian provinces and cities is the energy savings that
can result from this. The bill charged by PLN for street lighting electricity consumption every month often
makes up a significant share of the city budget. Switching to SSL also has co-benefits for local
governments, in particular improved public amenity and safety due to better illumination of roads at
night. Several cities in Indonesia already have some experience with the introduction of energy efficient
street lighting. Municipal public lighting agencies (PJU) in municipalities that are targeted to be involved
in the initial phases of the SSL NAMA include Yogyakarta, which started with meter installation from
2001 onwards and has achieved full coverage of all installed street lighting. Other cities with previous
experience include Semarang and others previously involved in GIZ-led activities, such as Malang,
Mojokerto, Pekalongan, Probolinggo and Surakarta as well as some other cities outside of Java such
as Makassar (South Sulawesi), which has achieved full metering and has some experience with
installation of LEDs. The SSL NAMA aims to build on this experience and accelerate the uptake of smart
street lighting technology across Indonesia between 2014 and 2019.
In relation to climate finance, the Government of Indonesia (GoI) is currently preparing different financing
mechanisms to support the implementation of the RAN-GRK. In light of the significant investment needs
required for addressing climate change in Indonesia, the Government decided to establish the Indonesia
Climate Change Trust Fund (ICCTF) to pool and coordinate funds from various sources including
international donors. The ICCTF channels funds towards climate change policies and programs in the
priority areas of land-based mitigation, energy and adaptation and resilience. The capacities of specific
financing mechanisms such as of the ICCTF are being further strengthened to acquire and administer
international financial support for NAMA implementation. In addition, the Ministry of Finance (MoF) offers
concessional loans for a range of infrastructure-related activities through the Indonesian Investment
Agency (PIP), including in the energy sector (in particular, renewable energy development, but also
potentially energy efficiency).
9
Alongside NAMA development and financing mitigation actions, Indonesia has already taken its first
steps toward a national MRV system. Guidelines including reporting templates for the Monitoring,
Evaluation and Reporting (MER) of RAN/RAD-GRK actions were published by BAPPENAS in May 2013
with support from GIZ PAKLIM5. The Ministry of Environment (MoE) is currently developing the concept
for the MRV system that includes the institutional set-up for MRV of unilateral/supported NAMAs. The
first Biennial Update Report (BUR) and the Third National Communication are currently being prepared
by MoE.
3.2. The technology context
When discussing energy efficient street lighting, mainly two technologies are seen as suitable
replacements for conventional lamp types: Light Emitting Diodes (LEDs) and Magnetic Induction
Lighting. This chapter gives an overview of the technological characteristics as well as main benefits
and challenges. The assessment is based on the following criteria:
Effectiveness and maturity: Assessment what illumination quality the lamps typically provide, how
reliable and mature the technology is, what the experiences have been regarding operation,
maintenance and lifetime.
Efficiency: Assessment of the characteristics regarding installation and operation costs.
Environmental impacts: Assessment of environmental impacts during production and
recycling/disposal phases.
Light Emitting Diodes (LEDs)
Light-emitting diode (LED) technology is a fast-evolving lighting technology with significant energy-
saving potential. The technology is based on semiconductor crystals where charge carriers (electrons)
are flowing and recombining with holes while originating photons (i.e. light). This process is called
electroluminescence effect. Hereby an applied external electric field across the semiconductors’ junction
will allow electrons in the conduction band, which are more mobile carriers than holes, to gain enough
energy to cross the gap and recombine with holes on the other side of the junction emitting a photon as
a result of the decrease in energy from the conduction to the valence band (radiative recombination).
Theoretically, it is possible that all free electrons recombine to create a photon. This suggests the high
energy efficiency potential of LEDs (see Halonen et al., p.111).
Effectiveness and maturity
Since the first commercially available LEDs in 1960, the technology has been constantly improving.
Today’s LEDs cover spectral emissions from the red to yellow region of the visible spectrum. White
LEDs can be realised by mixing the emission of different coloured LEDs or by the utilisation of
phosphors. Depending on the properties of the phosphor layers utilised, white light of different qualities
can be realised.
5 Policy Advice for Environment and Climate Change (PAKLIM)
10
Electrically, an LED is characterised by its forward current and forward voltage. Due to their typical
characteristic of representing the forward current as a function of the forward voltage, LEDs are called
current-controlled devices.
The electrical and optical performance of an LED is interrelated with its thermal characteristics. Due to
the inefficiencies resulting from the imperfections in the semiconductor and in the LED package
structure, heat losses are generated. These losses have to be removed from the device in order to keep
the operation temperature below the maximum allowed and avoid premature failure of the device. The
heat losses are firstly conducted to the exterior of the LED package throughout an included heat slug.
Next, the heat is realised to the ambient throughout convention and radiation. In some applications the
utilisation of an exterior cooling system such as a heat sink is required to facilitate the release of the
heat to the ambient (see Halonen et al., p.114).
Figure 2: Examples of LEDs and LED modules
(Zheludev, 2007; Kinzey, B.R., Myer, M.A., 2010,p 4)
Based on an average operation of 10 hours per day, LEDs have a life span of up to 13 years (Masthead
LED Lighting, 2009). The lifetime and performance depends on quality of the LED, system design,
operating environment, and other factors such as the lumen depreciation factor over a period of time.
Efficiency
Although the upfront cost of the LED is 2-4 times more than the cost of most high-intensity discharge
(HID) lamps, the energy consumed by the LED is half of the conventional lamp’s energy (or less) and
LEDs last longer than conventional lamps, resulting in significant savings. The LED fixture does not
require ballast or a capacitor; instead it converts the supply voltage to low voltage direct current, using
a small electronic power supply. Average annual maintenance costs are two times lower than that of
Mercury or HPS lamps (GIZ PAKLIM, 2012).
11
Environmental impacts
The U.S. Department of Energy (DOE) explored the environmental impacts of LEDs in comparison to
incandescent and CFL lamp types. Hereby the lighting production process, used raw materials, recycling
options and required energy resources have been taken into account. As a total result the currently
produced LEDs had a significantly lower environmental impact than the incandescent, and a slight edge
over the CFL. Main negative impact of LEDs is the waste landfill due to the lamp’s large aluminium heat
sink. It is expected that this impact will decrease due to efficiency improvements and recycling efforts in
the near future (Kinzey, B.R., Myer, M.A., 2013).
Summary of key advantages and shortcomings of LEDs
Advantages of LEDs:
Small size (heat sink can be large)
Physically robust
Long lifetime expectancy (with proper thermal management)
Switching has no effect on life, very short rise time
Contains no mercury
Excellent low ambient temperature operation
High luminous efficacy (LEDs are developing fast and their range of luminous efficacies
is wide)
New luminaire design possibilities
Possibility to change colours
No flickering, strobing, or noise
No optical heat on radiation
Disadvantages of LEDs:
High price
Low luminous flux / package
CRI can be low
Risk of glare due to high output with small lamp size
Need for thermal management
Lack of standardisation
Magnetic Induction Lighting
The burning time of discharge lamps is normally limited by abrasion of electrodes. It is possible to avoid
this characteristic by feeding electrical power into the discharge inductively or capacitively. Simply
stated, induction lighting is essentially a fluorescent light without electrodes or filaments, the items that
frequently cause other bulbs to burn out quickly (US Department of Energy 2013). The filling of the
discharge vessel consists of mercury (amalgam) and low pressure krypton. Like in fluorescent lamps,
the primary emission (in UV-region) is transformed with a phosphor coating into visible radiation
12
(Halonen et al., p.105). The technology is far from new. Nikola Tesla demonstrated induction lighting in
the late 1890s around the same time that his rival, Thomas Edison, was working to improve the
incandescent light bulb. In the early 1990s, several major lighting manufacturers introduced induction
lighting into the marketplace (US Department of Energy, 2013).
Figure 3: Induction streetlight
US Department of Energy, 2013
Effectiveness and maturity
Experience with using induction lighting at the U.S. Department of Energy's Waste Isolation Pilot Plant
(WIPP) near Carlsbad, New Mexico, has demonstrated the long life in actual usage. WIPP's first
induction lighting system was installed in 1998, replacing high-pressure sodium (HPS) lights. More than
10 years later, all but three of the original 36 induction units are still operating after more than 88,000
hours of continuous, 24/7 operation. Additional systems were installed in 2002 and succeeding years,
both indoors and outside, with excellent results.
Thus, many induction lighting units have an extremely long lifetime of up to 100,000 hours. To put this
in perspective, an induction lighting system lasting 100,000 hours will last more than 11 years in
continuous 24/7 operation, and 25 years if operated 10 hours a day. Some manufacturers only rate their
ballasts for 60,000 hours, even though the bulb may last longer (US Department of Energy 2013).
Efficiency
A long lamp life and good lumen maintenance can be achieved with these lamps because of the absence
of electrodes. The operation is virtually free of any maintenance of the electrical components. However
investment costs are significantly higher than for HPS or Mercury lamps. A study conducted by the U.S.
Department of Energy shows installation and equipment costs of induction lamps in the range of LEDs.
Energy consumption for generating similar illumination seems to be higher than for LEDs (see DOE
2012, p. 15)
13
Environmental impacts
As standard fluorescent bulbs, induction bulbs contain a small amount of mercury, although it is in a
solid state that makes it less harmful in case of breakage. Nonetheless, disposal of induction bulbs has
to be done responsibly at the end of their service life because of the mercury content (US Department
of Energy 2013).
Summary of key advantages and shortcomings of induction lamps
Advantages of induction lamps:
Virtually maintenance-free operation
High efficacy – in many cases, 60+ or 70+ lumens per watt
Long life
Excellent colour rendering index (CRI) – 80+ and in some cases 90+
Choice of warm white to cool white (2,700–6,500 K) colour temperature
Instant start and restrike operation
No flickering, strobing, or noise
Low-temperature operation
Disadvantages of induction lamps:
High price
Lower luminaire efficacy than LEDs
Higher electricity consumption than LEDs
Contains mercury
Lack of standardisation
Comparison of LED vs. induction lamps
The following Table 4 compares LEDs and Induction lamps as described above with other, typical street
lighting technology options.
14
Table 4: Fixture technology options for street lighting
Technology Mercury
Vapour
High-
Pressure
Sodium
Vapour
Induction New
Ceramic
LED
Relative Age
Oldest Newest
Description Older, very common white-light HID technology
Most prevalent HID light source for SL
White light Electrode-less light source with long operating life
White light HID technology; new CMH fixtures are >35 more efficient than previous CMH
White-light, directional, solid-state light source
Pros Low initial cost
Longer lamp life (~24k hrs)
White light
Sudden failures are un-common
Low initial cost
Longer lamp life (~24k hrs)
High lamp efficacy (70-150 lumens/ watt)
Virtually maintenance-free operation
High efficacy – in many cases, 60+ or 70+ lumens per watt
Long life
Excellent colour rendering index (CRI)—80+ and in some cases 90+
Choice of warm white to cool white (2,700–6,500 K) colour temperature
Instant start and restrike operation
No flickering, strobing, or noise
Low-temperature operation
• White light • Longer lamp life (24-30k hrs) • High lamp efficacy (~115 lumens/ watt) • High fixture efficiency
Small size (heat sink can be large)
Physically robust
Long lifetime expectancy (with proper thermal management)
Switching has no effect on life, very short rise time
Contains no mercury
Excellent low ambient temperature operation
High luminous efficacy (LEDs are developing fast and their range of luminous efficacies is wide)
New luminaire design possibilities
Possibility to change colours
No flickering, strobing, or noise
No optical heat on radiation
Cons Poor lamp efficacy (34-58 lumens/ watt)
Lower fixture efficiency 8 (~30%)
Contains Mercury
Low initial cost
Low CRI
Contains Mercury
High initial cost
Lower lamp efficacy (36-64 lumens/ watt)
Contains mercury
High price
Lower luminaire efficacy than LEDs
Higher electricity consumption than LEDs
Contains mercury
Lack of standardisation
High price
Low luminous flux / package
CRI can be low
Risk of glare due to high output with small lamp size
Need for thermal management
Lack of standardisation
Source: Table based on GIZ PAKLIM 2012, p.8
15
4. Smart street lighting NAMA implementation plan
4.1. Institutional framework
4.1.1 Existing institutional framework
The overarching institutional set-up for NAMA design and submission is currently under development in
Indonesia. The most preferred option being considered at present is to establish a panel that reviews
and approves NAMA concepts and proposals. This panel will most likely consist of the National Council
on Climate Change (DNPI), the Ministry of National Development Planning (BAPPENAS) as the
coordinator of RAN-GRK implementation, as well as representatives from the leading sector-relevant
ministries. Where the SSL NAMA is concerned, a number of key national ministries will need to be
involved.
Implementation of the SSL NAMA will require national leadership and coordination, as well as joint
management of actions at the provincial and municipal (city) government level. This is because it is the
municipal government which has responsibility for installation and maintenance of street lighting in the
urban/district areas, while the provincial government is responsible outside of the city. The National
Government is responsible for lighting on national roads.
The key actors that have been identified as having a relevant role/responsibility with respect to the
implementation of the SSL NAMA are summarised in the following Table 5.
Table 5: Institutional framework for the SSL NAMA
Institution Primary responsibility/interest Comments
Ministry of Energy and Mineral
Resources (MEMR)
Directorate General of
New/Renewable Energy and
Energy Conservation (EBTKE)
Directorate General of Electricity
(DGEEU)
Responsible for energy efficiency
policies and measures, including
energy efficiency standardization
for street lighting (includes LEDs).
Owner and champion of the SSL
NAMA with primary coordination
responsibility for energy efficiency
standardisation.
Responsible for metering regulation
with regards to PLN
MEMR will coordinate the efforts of
other key agencies involved in
implementation, including those
responsible for financing,
maintenance and installation and
performance standard setting.
EBTKE is logically the home of the
technical support unit
BAPPENAS Overall coordinator of Indonesian
NAMAs and agency overseeing the
ICCTF
Key stakeholder as ICCTF may be
a logical financing channel for
international finance to support the
SSL NAMA
16
Indonesian Climate Change
Trust Fund (ICCTF)
Fund established to help achieve
Indonesia’s goal of transitioning to
a low carbon economy.
Potential financing mechanism for
management and disbursement of
international (supported-NAMA)
funds.
Replenishment of ICCTF with a
combination of sources of finance
is required to enable NAMA
implementation.
Ministry of Finance (MoF)
Indonesian Investment Agency
(PIP)
Fiscal Policy Office
Agency responsible for
administering the national budget,
including financing for a range of
climate mitigation actions. MoF is
responsible for overseeing the
Indonesian Investment Agency
(PIP), which manages a key
financing mechanism for the SSL
NAMA.
Unit within MoF responsible for
giving recommendation on direction
for climate change policy
expenditure.
Key stakeholder as domestic
financing is required for scaling up
of the NAMA over time. PIP loans
could be used as one financing
option; other options also to be
considered.
Considering establishment of a
revolving fund for energy efficiency
improvement investments.
Ministry of Public Works (MPW) Responsible for standards of initial
street lighting investment,
luminance on road surfaces,
minimum distance of lighting poles
and lifetime of lamps on national
roads.
Relatively minor stakeholder
Ministry of Industry (MoI) Responsible for standards of
lighting products.
Key stakeholder for regulating
manufacturers in LED industry.
Standards for LED lamps for
households (not yet for street light)
are being drafted
Ministry of Transport (MoT) Responsible for standards for the
different components of the
furnishings that contain street lights
(i.e. poles, sockets etc.).
Costs for installation of lighting for
national roads are covered from the
MoT budget.
Key stakeholder for ensuring
standard on quality of luminaires
and intensity range on public street.
Ministry of Environment (MoE) Responsible for keeping track of
measured GHG emission
One of the key stakeholders to
ensure that GHG emission is
nationally recognised
17
National Standardisation Agency
of Indonesia
Responsible for facilitation and/or
endorsement of national standard
(SNI) for LED street light
Key stakeholder for ensuring that
an SNI is in place.
National electricity utility (PLN) Supplies electricity; charges local
municipal lighting agencies for
street lighting energy consumption;
recovers street lighting energy
consumption tax from consumers;
responsible for installation,
calibration and reading of meters,
Key stakeholder because of the
role of metering and the current
billing practice. PLN requires the
municipality to cover full installation
cost of metering and has little
incentive to provide metering itself,
but will process requests for
metering from municipalities. PLN
currently benefits from the standard
lump sum billing which tends to
result in bills that are significantly
higher than actual consumption.
Municipal public lighting
agencies (PJU)
Typically part of either the Local
General Works Agency (DPU) or
the Agency for Hygiene and
Landscape Gardening (DKP)
Under the Indonesian regulatory
framework, lighting for municipal
roads is financed out of the city’s
budget 6 . The municipality is
responsible for maintenance of all
street lighting, also on provincial
and national roads on the territory
of the municipality.
Have an incentive to install
metering and efficient lighting as a
way of reducing their energy bills,
but typically cannot afford to do so
without obtaining an increase in
their budget allocations.
Private sector companies
supplying efficient street lighting
equipment
e.g. Osram, Fokus and Philips
Commercial providers of equipment
supply contracts to local PJUs.
Members of the Association of
Lighting and Electrical Industries
(AILKI)
Philips has already sold over 3000
LED streetlights in Indonesia;
Osram has developed a financial
benefits calculation tool for
municipalities to demonstrate
payback periods.
International donors/financiers
German and UK Governments
via the NAMA Facility and
potentially others
Interested in efficient and effective
use of climate finance to support
mitigation activities in Indonesia
The SSL NAMA was submitted to
the NAMA Facility in its first round
call for submissions in September
2013
6 See Government Regulation No.34 of 2006, Para 1, Articles 8-9; Law no 22 of 2009, Article 25, and Government Regulation
No. 32 of 2011 article 33.
18
4.1.2 Challenges for the institutional framework
There are a wide range of challenges facing successful implementation of the SSL NAMA. Based on
the research undertaken for the preparation of this report, including interviews with stakeholders at a
national and local level between June – November 2013, the most important issues regarding the
institutional framework can be grouped under two broad issues:
Coordination of multiple agencies and actors
Addressing the incentive structure regarding billing and metering
Coordination of multiple agencies and actors
One of the key challenges to be overcome in the implementation of the SSL NAMA is the integration of
actions by the multiple institutions at the national, provincial and municipal level. The national level
agency which has ownership of the SSL NAMA and is responsible for its coordination is MEMR, as the
responsible authority for energy efficiency policy and measures. MEMR will need to achieve buy-in and
coordinate the efforts of several other agencies and actors to enable successful implementation. The
main coordination issues identified include:
Standard setting by MoI
While MEMR is responsible for setting energy efficiency levels that are to be considered in
technology/product standards, it is MoI which is responsible for performance standard setting for new
products in general. There is a need for cooperation between the two Ministries with MEMR taking the
lead as the owner of the SSL NAMA. It is likely that up to a 1-2 year time period is needed for the
establishment of a new standard for LED lamps by MoI7. Thus, alternative options may need to be
considered during the demonstration phase, such as using the International Electrotechnical
Commission (IEC) standard in the interim.
Financing by MoF
MEMR will coordinate with MoF as the primary agency responsible for administration of the national
budget. A key option for scaling up the SSL NAMA is by giving municipalities/provincial governments
access to concessional loans under the PIP investment scheme or a similar programme aimed at energy
efficiency improvement activities. This could also potentially involve Public-Private Partnership (PPP)
models for financing street lighting replacement, for example through supporting Energy Services
Companies (ESCOs).
Support from BAPPENAS
MEMR needs the support of BAPPENAS as the administrator of the ICCTF, which could be one of the
primary financing channels for international climate finance used to support the NAMA implementation.
7 Discussions with MoI in July 2013 indicated that the estimated timeframe for issuance of new standard (assumed that new
standard has references published by either IEC, JIS, ASTM) is 9 months where 6 months is for technical meeting and 3 months
for final review in BSN. MoI indicated that its preference is to wait for a LED standard until the corresponding IEC standards are
agreed.
19
In addition, it is BAPPENAS which is responsible for overall NAMA coordination, so the
roles/responsibilities need to be clearly defined between the two agencies, MEMR and BAPPENAS.
Coordination with provincial and municipal level governments
Participating provincial and municipal level governments will need to be triggered to act on a number of
levels including financial, technical and legislative. The overall coordination of the SSL NAMA will be the
responsibility of the Technical Support Unit (TSU) to be established within MEMR. The provincial
governments would be directly responsible for installation and maintenance in non-urban areas covered
by the NAMA, while municipal governments will be responsible for urban areas within each province.
Specific legislation may need to be passed by the provincial or municipal governments to enable
implementation, to allocate budgets for SSL investment activities and for certain financing arrangements
(e.g. for PIP loan repayments). From a financing perspective, the flow of funds between federal,
provincial government and municipal governments will need to be coordinated by MoF, as the agency
responsible for national financial affairs. A mechanism for coordinating grant funding for climate change
(including the amount of financial support for local governments) is currently being developed by MoF.
Currently, the variety of funding sources and channelling mechanisms available to stakeholders for
climate change actions are not yet coordinated according to a national financial mechanism (MoF,
2012a). Integration with provincial level action will be a key consideration, especially where gaining
access to finance is concerned.
Coordination with local municipalities’ public lighting agencies (PJU)
As the SSL NAMA will initially focus on pilot cities, it is critical that the PJU units of the cities chosen to
participate in the SSL NAMA have the capacity to implement and receive the necessary support from
the TSU. The PJUs will be responsible for replacement of the lighting technology, and, where relevant,
negotiating with PLN on metering installation and restructuring of the bill payment system. The local
municipalities are also critical at the MRV stage, and are likely to require considerable capacity building
support for this.
Coordination with the private sector
Private sector participants, in particular lighting manufacturers/suppliers such as Osram, Fokus and
Philips and potentially ESCO service providers, should be enabled to able to gain access to the market.
MEMR will be responsible for ensuring that barriers which may arise are addressed – for example
coordinating with local level governments if negotiations around supply of efficient lighting technology
are delayed due to national-level regulatory issues.
Addressing the incentive structure regarding billing and metering
Electricity metering for street lighting is an important factor for the success of the SSL. Several
Indonesian cities including Yogyakarta, Makassar, Malang and others have already embarked on a path
of installing metering. While the local municipalities have a strong incentive to install metering, since it
helps them reduce costs, they often cannot afford to do so on their own, and progress has been slow to
date. PLN, which charges the cities for their street lighting consumption on a monthly basis, has little
20
incentive to help facilitate a more rapid shift to metering because of the likely over-charging that is
currently taking place in the absence of metering (this is discussed in detail in Section 4.2). The current
practice of lump sum billing generates bills up to 30-50% higher than actual consumption. This situation
is likely to be due a range of factors, including the calculation approach used by PLN and the widespread
illegal tapping of the distribution grid. From a security of supply point of view PLN arguably has an
incentive to prevent this theft, but a widespread shift to metering would almost certainly have an impact
on the revenue received from local governments for street lighting.
The local (regional) PLN office generally accepts metering requests from municipalities but requires the
municipality to cover full installation costs which are in the order of 20m Rp (around 1780 USD) per 3-
phase meter, which serves up to 20 lamps. PLN has to provide the meter which itself only costs around
1m Rp per unit (88 USD). Metering requests need to be sent by the municipality to the local PLN office.
PLN will then propose the number of meters to be installed and negotiate the rest of the installation.
PLN also calibrates the meters and is responsible for checking meters.
This payment structure and separation of responsibilities creates the potential for disincentives on the
side of PLN to actively support the roll-out of metering. In a positive development, PLN is spending 1
million USD topped up with additional funds from the Asian Development Bank (ADB) for a LED street
lighting pilot in Surabaya and Denpasar, with implementation from 2014.
To address the identified challenges, there needs to be a high level political commitment to fixing the
incentive structure, prioritising metering and clear structuring of the responsibilities in the implementation
of the SSL NAMA. The implementation of this will require active coordination by the NAMA owner,
MEMR, to ensure that all actors are playing their role.
4.1.3 Establishment of technical support unit (TSU)
It is envisaged that a Technical Support Unit (TSU) in the coordinating institution, logically EBTKE, within
MEMR, should be established to facilitate the implementation of the SSLI NAMA, and coordinate the
activities of all of the involved agencies. Part of the international grant funding component will be for the
purposes of technical assistance (TA) to the various actors involved in the implementation of the NAMA.
With support from GIZ, the TA funding is proposed to be used to for this. The TSU will be the primary
institution responsible for coordination of the various agencies involved, and providing technical
assistance/capacity building activities where needed.
The key TA functions of TSU would include:
Policy advice for reform of street lighting tax policies, pricing regulations and related policies,
including the prioritisation of electricity metering.
Providing technical support to provincial and/or municipal level governments in their applications for
financing from national government agencies including PIP.
Technical advice as an input for the formulation of national energy efficiency standards for street
lighting products.
21
Awareness raising at the city and provincial level, especially during the scaling-up phase of the SSL
NAMA (including on ESCO contracting, design and implementation).
Technical support on installation, maintenance and MRV of smart street lighting systems in
municipalities.
For an overview of the activities of the TSU over the lifetime of the NAMA see the Table 6 below.
Table 6: Outline of SSL NAMA Technical Support Unit (TSU) within MEMR
Overall
purpose
Coordination of actors/agencies involved in the implementation of the SSL
NAMA at the national, provincial and municipal level
Provision of technical assistance on policy, financing and technical issues
to support the efficient and effective implementation of the NAMA
Functions Phase I: Demonstration phase (2014 – mid 2015)
National level
Provide technical support and advice to the relevant ministry (MoI or MEMR) for
the establishment of energy efficiency performance and safety standards for
efficient lighting products at the national level.
Accreditation of auditors and training bodies to enable adequate technical
capacities for installation and monitoring of street lighting technologies.
Provide policy advice to MEMR on priority policy issues including electricity
metering and a regulatory framework to enable ESCO contracting by cities.
Formulation of policy reform options to enable more efficient scaling-up of smart
street lighting, including: reform of taxation policy at the city level and electricity
pricing regulations through reduction of subsidy (e.g. phasing in of more cost-
reflective pricing).
Interacting with PIP to help reduce bottlenecks/streamline procedures for loan
applications. This includes dealing with issues such as the creditworthiness of
municipalities and regulatory requirements regarding loan repayments.
Setting up and maintaining a monitoring database required for emissions MRV.
Provincial/municipal level
Provide information via awareness campaigns on the benefits of smart street
lighting and metering for city and provincial level governments.
Provide education and training for provincial/municipal governments on correct
installation and maintenance procedures and MRV of smart street lighting activities
(including measurements required for monitoring emissions reductions).
22
Providing technical support to provincial and/or municipal level governments in
their applications for financing for lamp replacement under the SSL. Initially this will
focus on two main financing options:
1. Capacity building to help local governments access grant finance channelled
through ICCTF when administering international NAMA support.
2. Supporting local governments in accessing concessional loans administered
by PIP.
Support PJUs in conducting audits of the number of lamps installed – such
assistance is already provided by MEMR and could be expanded. For example, to
support cities in negotiating with PLN or in designing surveys.
Awareness raising and promotion of the ESCO model, including on the design of
contracting arrangements, dealing with national regulations regarding
tendering/contracting, and the successful implementation of ESCO-financing.
Phase II: Scaling-up phase (mid 2015 – 2016)
National level
Supporting MEMR in the implementation of policy reform options identified in
Phase I.
Exploration of longer term financing options such as a dedicated facility targeting
energy efficiency loans managed by the national government (e.g. MoF).
On-going interaction with agencies responsible for standards (MoI, MEMR).
On-going and increased interaction with agencies involved in financing, in
particular PIP/MoF, as the use of concessional loans is anticipated to play a major
role for supporting cities wishing to join the NAMA.
Enabling the uptake of ESCO contracting by licensing/accrediting ESCOs to give
local governments greater confidence in the reliability/quality of their services.
On-going maintenance and improvement of the monitoring database, including for
reporting of NAMA progress at the national/international level.
Provincial/municipal level
Expanded awareness-raising of the SSL NAMA benefits at the city and provincial
level to promote uptake (in particular, cities outside of Java).
Technical assistance including training of additional local government PJUs on
maintenance and MRV procedures.
Trouble-shooting support for cities that have already joined the SSL NAMA in the
first phase, for example, in dealing with ESCO arrangements or MRV issues.
23
Facilitation of ESCO financing in 1-2 cities by supporting local governments in the
development of necessary legislation to enable contracting, in preparation of tender
documents and so on.
Supporting additional municipal/provincial governments in their PIP loan
applications.
Phase III: Transformation phase (2017 – 2019)
National level
Supporting MEMR in the implementation of policy reform options identified in
Phase II.
Development of options and budgeting plan for the long term functions of the TSU
beyond the SSL NAMA implementation. One option is to adopt a broader Energy
Efficiency (EE) focus as an Indonesian Energy Efficiency Agency (similar to India’s
BEE (Indian National Energy Efficiency Agency)).
Coordinating with national government level agencies involved in financing SSL.
Maintaining the monitoring database including for NAMA reporting at the national
and international level.
Provincial/municipal level
On-going support for cities involved in the SSL NAMA as per Phase II, including for
new cities joining in Phase III.
Promotion of its benefits to expand coverage nationally.
On-going support for cities in preparation of financing applications and when
entering into ESCO arrangements.
Staffing
needs
At a minimum the following staff is foreseen to be required in Phase I-II of the NAMA:
Manager/general coordinator: senior level manager, experience coordinating
complex projects involving multiple agencies; international experience and ideally
energy efficiency expertise.
Finance coordinator: finance background, responsible for direct interaction with
ICCTF/BAPPENAS, PIP/MoF and municipal/provincial budget officers; supports
local governments with related application procedures and guides capacity building
efforts.
Technical coordinator: engineering background; responsible for interaction with
MoI on standardisation, supporting local government PJUs on installation and
MRV, including guiding the development of training programmes, and responsible
for interaction with PLN on metering issues.
24
Figure 4 below provides an illustration of the proposed structure of the TSU. Further detail on each of
its functions is provided in the following sections, in particular in relation to its role in MRV and awareness
raising/capacity building.
Figure 4: Organizational set-up of Technical Support Unit (TSU) within MEMR
4.2. Policy and regulations
This section briefly discusses the current regulatory framework relating to the pricing of electricity
consumed by street lighting, the mechanism for recovery of the associated costs from the public and
the related policy framework. It aims to identify policy reforms which could help incentivize provincial
and municipal governments in shifting to more efficient lighting technology.
4.2.1 Assessment of existing pricing policies and regulations
At present, there are a number of barriers to street lighting efficiency improvement arising from the way
in which electricity pricing and cost recovery is structured. Firstly, as already mentioned, in the absence
of metering of street lighting in many Indonesian cities, the level of consumption is estimated and billed
Technical support officers: up to three support officers who are responsible for
carrying out training courses on installation, maintenance and MRV.
Administrative support staff: up to two administration and office support staff to
maintain databases, organise workshops, meetings, information mail-outs,
webinars, local briefings and awareness raising sessions and support the
technical/financial/managerial team in its work.
Estimated
budget
Total estimated budget of 5.5m EUR spread over the implementation period 2014-
2019, includes salaries, operating costs, and other external costs.
Financing
options
Technical assistance component of NAMA Facility grant channelled and managed
through GIZ acting as the implementing agency. By the end of the transformation phase
(end of 2019) an alternative funding approach will be defined.
25
by PLN on a lump sum basis. Where there is partial metering of street lighting, the local government
receives a bill from PLN which includes a component based on metered data, and a component
estimated on a lump-sum basis. This estimation is done using a set of conservative assumptions
including 375 hours per month of operating hours and an adjusted power rating based on technical
specifications of the lighting technology, which results in the highest possible consumption being
calculated for the number of assumed connections. Presidential Decree No. 89 of 2002 governs the
formulation to define effective power (VA) of lump sum payment which results in an assumed minimum
value twice the installed power rating as shown in the Table 7 below.
Table 7: Effective Power Rating of street lighting lamps
A. Gas Discharge Lamps
No Lamp Power Rate Effective Power (KVA)
1 10 - 50 100
2 51 - 100 200
3 101 – 250 500
4 251 - 500 1000
B. Incandescent Lamps
No Lamp Power Rate Effective Power (KVA)
1 25 - 50 50
2 51 - 100 100
3 101 – 200 200
4 201 - 300 300
5 301 - 400 400
6 401 - 500 500
7 501 - 600 600
8 601 - 700 700
9 701 - 800 800
10 801 - 900 900
11 901 - 1000 1000
The exact number of lamps connected to the PLN distribution network is highly uncertain in many
Indonesian cities due to the practice of residents (households and businesses) illegally connecting. For
example, in one city in Java, Surakarta, discussions with the PJU revealed that of an estimated 17,360
lamps in total around 40% of these are likely to be illegal connections8. Its last full audit of the number
of lamps was done in 2007. The PJU expects that further illegal connections have been added since
8 Two aspects related to illegal connections are: firstly, where people install a lamp without notification to the PJU so the lamp is
not accounted for by the PJU; and secondly, the technical connection does not fulfill the standards (cabling type, lamp type)
26
then but does not know how many. PLN bills the city based on the total number of connections from the
2007 audit (including illegal connections). The city has metering covering around 30% of all street
lighting, but this reflects only 16% of its street lighting electricity bill - the remainder (84%) of its bill is
based on the lump sum approach. Tax revenues have been increasing due to population growth, but
barely keeping up with the growth in the electricity bill; both are expected to reach around 30bn IDR in
2013, with little room for increasing the tax which is already set just under the maximum limit at 9%9.
That is, the tax covers consumption alone, with new installations, maintenance and any replacement
programmes needing to be financed by other means.
Secondly, the disconnect between the tax revenues and the expenditure on street lighting via the PJU
does not encourage investment in more advanced and expensive technology. The street lighting tax is
defined by the national law (UU) 28/2009 (para 55-56) and the rate can be set by the municipal council
through a local decree (Perda). The regulation contains specific provisions restricting the level: up to a
maximum of 10% for regular household, business customers, up to a maximum of 3% if the electricity
is used by certain industries including mining and the oil and gas sector, or generated from other sources
(usually PLN), and up to a maximum of 1.5% if the user is a captive power user. The table below provides
a summary of the tax levels charged by a number of different cities/regions. As can be seen, most cities
in
Table 8 are already at or near the maximum possible level of the tax (10%). The actual money is
collected from end customers by PLN on behalf of the municipality. PLN then transfers the collected
money to the municipal government.
9 Interview with Surakarta PJU in August 2013.
27
Table 8: Overview of street lighting taxes for selected cities in Indonesia
City Tax rate on street lighting energy
consumption
(Note: rate for regular consumers other than
restricted industries and users of captive power)
Source
Yogjakarta 8% Perda No. 1 of 2011
Pekalongan 9% Perda No. 5 of 2011
Surakarta 9% Perda No. 4 of 2011
Probolinggo 10% Perda No. 2 of 2011
Blitar 10% Perda No. 7 of 2011
Malang 7% Perda No. 16 of 2010
Semarang 5-9% (different categories of users) Perda No. 7 of 2011
Salatiga 9% Perda No. 11 of 2011
Medan 7.5% households; 10% businesses Perda No. 16 of 2011
Makassar 10% Perda No. 3 of 2010
Mojokerto 10% Perda No. 12 of 2010
Because the tax is levied for the purpose of financing street lighting services, the public feels an
entitlement to having lamps directly outside their homes and businesses. This is one of the main drivers
for the illegal connections. However, since the tax is not linked to the actual consumption of electricity
from street lighting, including from such illegal connections, it has no impact on electricity consumption.
In addition, since the receipts flow into the municipal government’s consolidated (general) budget, the
city PJU is not able to directly link tax receipts to the required investment in energy efficiency lighting.
Even in the case of cities which have achieved full metering and have adequate tax earnings to cover
street lighting energy consumption, such as Yogyakarta, the PJU still relies on the municipal government
and legislative for budget allocations to cover its costs. Increasing the tax would therefore not
necessarily mean the PJU will receive additional funding which can be used for a LED replacement
programme, for example. In addition, since most cities have already reached the 10% tax limit, or are
near this limit, it is not an available policy lever for raising finance for energy efficiency improvements.
Even where this is theoretically possible it is generally not seen as being a likely option, as is discussed
below.
The diagram below (Figure 5) illustrates the cost-recovery and payment mechanism that is currently in
place in Indonesian cities.
Figure 5: Cost recovery and payment mechanism for street lighting electricity
28
Thirdly, electricity prices in Indonesia are subsidised more generally, such that PLN is unable to recover
the full costs of its supply from its customer bills; this creates a disincentive to move away from the
current pricing mechanism for street lighting. Nation-wide, the average cost of power produced by PLN
in 2010 was IDR 1089/kWh (1.03 US cents/kWh), while it only recovered on average IDR 693/kWh (6.57
US cents/kWh)10. Even in Java-Bali where prices are more reflective of the cost of generation than
elsewhere in the country (where average generation costs are higher) there is a need for government
subsidisation of PLN’s operations (World Bank, 2005). If fully cost-reflective electricity pricing were
introduced, there would be less reason for PLN to resist the move to cost-reflective pricing of street
lighting consumption, which tends to over-estimate consumption, since its operations would be funded
by the income received from its customers. At present, essentially many Indonesian cities are being
overcharged for their street lighting consumption and this helps to offset PLN’s losses elsewhere in the
system.
Increasing electricity tariffs would encourage investment in more efficient technology on the side of the
provincial/municipal governments and result in greater tax receipts from the public to help finance this.
From PLN’s point of view, improvement in energy efficiency of street lighting would help ease capacity
constraints, especially during peak times.
4.2.2 Available options for reforming pricing policies and regulations
To overcome the above barriers, there are a number of regulatory reform/policy options that could be
considered further. These are briefly discussed below.
Reforming the street lighting tax regime
10 http://www.pln.co.id/sulselrabar/?p=799
29
If regulation allowed for higher tax levels, the municipal or provincial governments could be directed
(e.g. by presidential decree), to increase their street lighting taxes as a way of financing the LED roll-out
themselves. However, there are a number of issues with this approach. Firstly, this would essentially
result in the national government shifting the burden of funding the roll-out onto consumers. Local
governments would be forced to deal with the political fallout that would result from this and many would
be likely to oppose it as an option. In addition, there would be practical challenges in defining a
nationally-harmonised approach since cities/regions already charge different tax rates and have
different budgetary circumstances (some can self-fund their street lighting activities already, while others
are running a deficit due to the number of illegal connections and the lump-sum billing).
If left on a voluntary basis, some city governments may determine that a tax increase is an appropriate
option if they have not already reached the maximum limit. For example, discussions in Malang indicated
this could be an option: currently a 7% tax is charged from consumers, which could be increased up to
10% to help finance street lighting activities. However, there will be different considerations facing cities
when making this determination. Firstly, the roll-out would compete with alternative uses of the tax
revenues such as reducing budget deficits and other infrastructure investments. The PJUs would still
need to fight for the increased budget allocation due to the non-hypothecation of tax revenues to specific
uses. Secondly, the tax increases may be politically unpopular with citizens. Finally, from an equity
perspective it is also questionable for consumers to be forced to finance the roll-out when the cost
savings associated with it will flow to the local government, unless the benefits are redistributed
somehow.
Reforming the approach which PLN uses to calculate the consumption on a lump sum basis
Discussions with city PJUs have indicated that there is no transparent process in place for changing the
way that consumption is calculated by PLN after energy efficient street lighting is installed. If a city PJU
replaces a series of inefficient lamps with more efficient technology, it would expect PLN to consider the
resulting electricity savings when calculating the bill for each month. However, the current lump-sum
payment system does not distinguish between different types of lamps and their efficiency – the same
price is effectively charged for a 400W lamp as for a 1000W lamp (GIZ PAKLIM, 2012). Consumption is
also based on a flat rate, which is not effective of peak time consumption, due to the relatively low level
of metering in most cities up until now. As it is moving towards full metering, a city expects that the
monthly bill will be shifted from the lump sum-billing practice to billing based fully on metered data.
Anecdotal evidence gathered during discussions with city PJUs suggests that a common scenario is
that the city PJU must approach PLN and negotiate this transition through a rather non-transparent
process which can take time and careful diplomacy. The number and type of installed street lighting
needs to be validated by PLN before it will change the way in which consumption is calculated. In some
cities, there are on-going disputes between PJU and PLN over the number of connections. Until the
negotiations and validation are completed, it is likely that the monthly bill from PLN will remain the same
as it was prior to the efficient lamp replacement. Thus, there is a reduced incentive on the PJU to invest
30
in more expensive and efficient technology because it is uncertain if and when the benefits will be
reaped.
Discussions with PLN during the preparation of this report indicated that there is indeed a willingness to
move to metering, and a commitment to respond to a city’s request for installing metering in a timely
manner. More open dialogue between officials from the Municipal Government side and the PLN side
could help resolve issues on metering and billing. This will require leadership from senior staff at PLN
to ensure that officials in regional offices are aligned with overall company policy and directions.
A clear set of national rules setting out the procedural steps, timeframes, and obligations to be followed
by both the city PJU and PLN to ensure a speedy transition to cost-reflective billing would reduce
transaction costs and create a greater incentive to replace inefficient lamps with more efficient
technology. These rules could include both a metered and non-metered scenario, to enable efficiency
improvements to proceed on both tracks. A specific issue that needs to be addressed is to determine
how to incorporate LED and other smart lighting technologies into the PLN pricing structure. LEDs may
not fit easily into a tariff system designed for conventional gas-release lamps.
Wider reform of Indonesian electricity pricing
Removing or reducing energy subsidies in Indonesia have long been the subject of discussion, including
the debate about moving electricity to a cost-reflective tariff regime. It is important to recognise the scale
and hence implications of this issue for the national economy: the total value of electricity subsidies
provided by MOF to PLN reached over IDR 90 trillion (9bn USD) in 2011 (IISD, 2012). Street lighting is
but one small element of the national electricity consumption profile.
The Indonesian government understands the reasons for removing energy subsidies, which tend to
benefit the wealthy more than the poor, and has made efforts to do so in the past. MEMR is planning to
take gradual steps towards the removal of electricity subsidies, starting with big industry, based on the
decision from Working Committee of the House of Representatives in September 2013. A statement in
2010 by the then energy minister indicated subsidies should be removed by 2014, but this will happen
gradually, with protection of low income people remaining in place (Jakarta Post, March 23, 2010)11.
Expectations for more widespread reform of electricity subsidies in the near term must be considered
against the backdrop of the demonstrations seen earlier in 2013, which were held in protest against
reduction of petroleum subsidies, and the upcoming presidential elections in 2014. More far-reaching
electricity pricing reform is seen as being an unrealistic option in the timeframe for starting the SSL
NAMA implementation, which is intended to run over 2014-2019. Electricity pricing reform at a national
11 http://www.thejakartapost.com/news/2010/03/23/govt-expects-remove-electricity-subsidy-2014.html
31
level takes considerable time to develop options, achieve political support, draft legislation and obtain
approvals from the House of Representatives. Coming into an election year this is particularly
challenging. Wider removal of electricity subsidies is hence seen as an unrealistic option for stimulating
the SSL NAMA until after the election. At that point in time, it may become clearer whether electricity
pricing reform could play a role later on in the NAMA’s timeframe.
Metering
Perhaps the most important factor for a successful SSLI NAMA implementation is increasing the pace
and coverage of electricity metering of street lighting. Currently only a few of the Indonesian cities being
considered as priority cities for the SSLI NAMA have reached full metering, as shown in the Table 9
below.
Table 9: Metering rates in Indonesian cities being targeted for the SSL NAMA
City Metering rate (%)
Yogyakarta 100
Semarang NA
Surakarta 30
Malang 50
Probolinggo 10
Pekalongan 17
Makassar 95
Cimahi 95
Source: Interviews with municipal PJUs in August-September 2013
While full metering is not necessarily recommended as a pre-condition for participation in the SSL
NAMA, a more rapid move to this would enable a smoother and more successful implementation, for a
number of key reasons.
Financial
Metering avoids the need for lump sum-billing by moving to fully cost-reflective pricing of street lighting
electricity consumption. This reduces the burden on PJU budgets, freeing up money for energy
efficiency improvements and leaving more funding available for the NAMA from national and
international sources.
32
Monitoring of outcomes
If metered data can be used to monitor and report on progress of implementing the SSLI NAMA this
would be more accurate than estimation based on an assumption of the number of lamps and monitoring
the operating hours of those lamps (see MRV section).
Cost estimation
Inadequate data on the number and type of lamps, number of illegal connections etc in unmetered cities
makes the estimated investment requirements for the SSLI NAMA somewhat uncertain. To deal with
this, contingencies need to be built into the analysis (see the Financing section). Increasing metering
would significantly reduce this uncertainty, and help make a stronger case for both domestic and
international financing to support for the SSL initiative.
Increasing the metering of electricity consumption from street lighting is already being pursued by city
governments because of the financial benefits of avoiding the lump sum billing approach. Almost all city
PJUs interviewed during the research undertaken for this report indicated a strong desire to reach full
metering and were interested in any form of support that might be provided. The role of the national
government of Indonesia could be to accelerate this process by making it a policy priority. National
government support could be provided in a number of ways, for example by facilitating greater
cooperation on the side of PLN, and/or by providing financial support to cities which are unable to self-
finance metering easily from within their municipal budgets. The support could be provided by the
national government in conjunction with the SSL initiative, via a package of soft loans provided by PIP
for example. PIP would be more willing to offer loans for metering if PLN is fast in adjusting the city’s
billing, since this would enable the cities to pay back the loan amount through the savings generated
more quickly. If the modernisation of the street lighting network were defined as a national priority by
MEMR this would also open up the possibility for (Special Allocation Fund) DAK grants to be made
available to cities which cannot finance a more rapid roll-out of meters themselves. Funding of the
metering component with domestic sources could thus be counted as part of the “unilateral NAMA”
component of the SSL NAMA.
4.2.3 Possible next steps
The following pricing policy and related reform options are considered:
1. MEMR envisages to consult with PLN on a transparent procedure for the calculation of
consumption of electricity from efficient street lighting. This would help reduce transaction costs
and increase the incentive for PJUs to invest in more efficient lighting. Two tracks are
recommended – one with and one without metering.
2. MEMR envisages to facilitate a more rapid move to full metering of street lighting in Indonesian
cities by offering facilitation and/or financial support. This would help incentivise cities to switch
to more efficient lighting technologies and ensure the SSL NAMA is implemented more
successfully.
33
4.3. Baseline data
4.3.1 Availability of national data on street lighting energy consumption
The annual energy consumption of street lighting at a national level is stated in the Handbook of Energy
and Economic Statistics of Indonesia, published yearly by the Centre for Data and Information on Energy
and Mineral Resources within MEMR (ESDM energy statistics, 2012). In 2011, street lighting accounted
for 3,068 GWh of electricity sales by PLN. These statistics are made up of a metered and non-metered
component. The non-metered component, as was discussed earlier, is likely to overestimate
consumption in many cities since PLN has an incentive to charge local governments for the maximum
possible consumption and the approach used for estimating street lighting electricity usage is designed
to ensure this outcome. Disaggregated data on street lighting energy consumption at the city level is not
published by MEMR.
According to GIZ PAKLIM (2012), street lighting accounts for a significant share of GHG emissions from
local government operations and contributes significantly to costs, as shown in the Table 10 below.
Table 10: Contribution of street lighting to local government GHG emissions
City Baseline emissions Street lighting as a % of total
GHG emissions from govt.
operations
Electricity bill p.a.
IDR billion
Surakarta 17,173 tCO2e 77 18.9
Yogyakarta 7,775 tCO2e 82 7.2
Pekalongan 6,910 tCO2e 76 10.3
Salatiga 2,287 tCO2e 20 3.2
Source: GIZ PAKLIM (2012)
Data on electricity consumption can be obtained from the individual PJU divisions at the
provincial/municipal government level, but is of mixed reliability without metering. Reliable metered data
is only publicly available in very few municipalities - one positive example is Makassar, which publishes
monthly metered data online. Interviews conducted with PJUs during the research involved in this report
identified the lack of validated, consistent data on the number and type of street lights installed in
Indonesian cities as a key risk factor in the successful implementation of the SSL NAMA. Unless cities
have achieved full or near full metering, or have recently conducted a full audit, there is likely to be
considerable discrepancies. In the case of the cities in Java interviewed during the research for this
report, the estimated number of illegal connections ranged widely, for example:
Blitar – estimated to account for around 10-20% of all consumption
Probolinggo – estimated to account for 60-70% of all connections
Surakarta – estimated to account for 40% of all connections
Pekalongan – estimated to account for 20% of all connections
34
Thus, both the national level data published by ESDM and the PJU data should be treated with caution
unless there is metering in place.
4.3.2 Identification of a suitable baseline determination approach
Widespread metering would provide more reliable data, and could help identify the cause of the losses
(depending on the metering design). However, it is not realistic for a full-scale national roll-out of
metering to be required for all cities as a precondition for the implementation of the SSL NAMA. Firstly,
the costs are likely to be prohibitive (see section on financing needs for the SSL NAMA). Secondly, the
timeframe for such a roll-out would prevent utilisation of the financing options identified for the intended
timeframe of the SSL NAMA. Thirdly, metering of street lighting may not be essential for monitoring of
the energy savings and hence emissions reductions that will result from the SSL NAMA, as is discussed
below. This is not to say that metering should not be a matter of national policy priority, but simply that
from an emissions point of view there is another approach available – taken from the CDM – for
establishing the baseline.
An alternative approach is to calculate baselines for each city/province utilising municipal/provincial level
data on street lighting (number of lamps installed, type of lamp, rated wattage, operating hours etc).
These calculated baselines can then be confirmed/adjusted ex-post during the monitoring phase. This
approach does not avoid the need for reliable data on the number and type of lamps installed, so at the
very least a recent (e.g. within the last three years) audit or numbers of lamps validated by PLN should
be required from a city as a pre-condition for joining the SSL NAMA. Otherwise, the monitored results
could be quite different from expectations based on ex-ante assumptions.
The approved CDM methodology AMS-II.L Demand-side activities for efficient outdoor and street
lighting technologies defines certain criteria for deriving the baseline situation and can be applied in the
context of deriving a baseline for the SSL NAMA. It provides for the following:
Estimation of electricity consumption in watts multiplied with operating hours.
Operating hours need to be measured (using sampling) ex-post through e.g. brightness sensors or
schedules. Alternatively conservative, regional default values for day light time can be applied.
Lighting technologies covered by the methodology include all luminaires (LEDs and other
technologies) and related equipment such as control systems that decrease electricity consumption.
The applied technology must be new equipment/not transferred from another city.
In the CDM methodology, monitored data through meters is not required. Rather, lamps that fulfil certain
standards are sufficient for deriving the baseline.
4.3.3 Key baseline parameters
As the baseline will be different for each city participating in the SSLI NAMA, the discussion in this
chapter is on a general level, covering the key baseline parameters that are valid for all assessed
options. Average values have been calculated that allow a theoretical up-scaling of lamps under the
35
different scenarios in Section 4.5. We distinguish between technical, financial and emission related
baseline elements.
Technical baseline parameters
Important technical parameters for the baseline can be taken from the CDM methodology outlined
above. In particular, this includes the number, type and rated wattage of the lamps installed in the
municipal or provincial roads. For many cities researched as part of preparing this report, this data was
obtained directly from the PJUs. However, for the purposes of estimating the baseline energy
consumption of additional cities that might join the NAMA during its scaling-up, it is simpler and
necessary to derive the baseline using assumed average values for a hypothetical “model” city. This
can be done based on the average number of lamps per inhabitant in an average Indonesian
small/medium/large sized city, the lamps per road km and the typical wattage per installed lamp, using
a weighted average approach for the different lamp types, based on the lamps installed in cities where
better quality data is available. The most common lamp types that have been installed in the past are
Mercury 250W and different kinds of High-Pressure-Sodium (HPS) lamps.
Table 11: Technical parameters for baseline estimation
Parameter Truncated mean* baseline value
Number of lamps per inhabitants 1/47
Lamps per road km 39
Wattage per lamp 205
Operation hours per day 12
Typical lifetime of average lamp (in hours) 24,000
*Truncated mean is the average of a number of values discarding the highest and lowest value
Source: Assessment of seven Indonesian cities, based on GIZ PAKLIM (2012)
Financial baseline parameters
Aside from the technical parameters there is a financial baseline for the business as usual scenario. Key
financial elements are listed in the following Table 12. Among these are typical costs per lamp and
related civil works and O&M, the electricity tariff and the average tax levels that create current funds for
financing street lighting.
Table 12: Financial parameters for baseline estimation
Parameter Baseline value
Costs per HPS lamp (150W) 246 USD
Costs per Mercury lamp (250W) 226 USD
Civil work costs per lamp 48.6 USD
O&M costs per lamp 6.7 USD (8 USD for years 4 and 5)
36
Electricity tariff in 2014 75 USD/MWh
Average street lighting tax level 7%
Average street lighting revenue per
inhabitant
3.9 USD/year
Source: Assessment of seven Indonesian cities, based on GIZ PAKLIM (2012)
Emissions baseline parameters
A main focus of the NAMA will be on achieving emission reductions. Therefore the setup of a realistic
emissions baseline is essential for assessing the mitigation impact of efficient street lighting. In addition
to the technical parameters listed in the Table 13 above the other key parameter for estimating the
emissions baseline is the respective grid emission factor (GEF) for each of the Indonesian cities which
could potentially be covered by the NAMA, as outlined below.
Table 13: Grid Emission Factors relevant for cities targeted under the SSLI NAMA
Grid Cities targeted under the SSL
NAMA connected to this grid
Grid emissions factor
(kg CO2-e/kWh)
Jakarta Madura Bali Grid
(JAMALI)
Yogyakarta, Pekalongan,
Surakarta, Probolinggo, Blitar,
Malang, Semarang, Salatiga and
Mojokerto
0.741
Sumatera Grid Medan 0.748
Sulawesi-Selatan-Sulawesi-
Barat Grid
Makassar, Sulawesi Selatan 0.601
Minahasa-Kotamobagu Grid Manado, Minahasa 0.319
Source: MEMR (2012)
Using the above information, an emissions baseline can be established quite easily for each of the cities
joining the SSL NAMA. The way this baseline can be used to calculate emissions reductions is explained
in detail in Section 4.6.
4.3.4 Recommendations
In general, a better understanding of the discrepancies between officially published street lighting
consumption statistics and the real situation in Indonesian cities is required. In particular, there is a need
to understand the different components of electricity losses in the baseline situation and their relative
37
contribution - i.e. the share of line losses vs. degradation of equipment vs. illegal connections/theft. This
is recommended as an area for further exploration following the release of this Implementation Plan.
Once these issues are better understood, it may be possible to use official national statistics to calculate
the baseline for cities during the further expansion of the SSLI NAMA.
In the meantime, it is recommended to impose a requirement on cities wishing to join the SSLI NAMA
that they have at least one of the following:
a) The city has metering in place to cover a minimum percentage of street lighting load (e.g. above
50%); or
b) The city has conducted an audit within a minimum timeframe (e.g. within the last 3 years prior to
joining the NAMA).
It is also recommended that the baseline for individual cities/municipalities joining the SSL NAMA in the
demonstration phase should be established on a city-by-city basis using the following approaches:
a) For cities where full coverage metering has already been installed or is soon to be installed, it is
recommended to use the metered data for baseline establishment.
b) For the non-metered component of the consumption (up to 50%), use the calculated approach as
outlined in this section and in Section 4.6.2 (where the emissions reduction equations are included
based on approved CDM methodology AMS-II.L).
c) When applying option b), emissions reductions calculated ex-ante should be verified ex-post during
the monitoring phase, as is outlined in Section 4.7.
4.4. Performance and safety standardisation for LEDs
4.4.1 Background
The Indonesian National government is making efforts to improve demand side management through
various energy efficiency and conservation programs. LED street lights were implemented on a pilot
scale in a few Indonesian cities to study the technical performance and to exhibit energy and cost
savings over conventional lighting to the local governments. A few companies have also started
manufacturing LED chips in Indonesia, which are the key component in all LED lighting products. To
date, Indonesia does not have any standards for LED street lighting. Acceptance of LED based street
lighting by local governments is a key factor in determining the large scale implementation of the SSL
NAMA. In view of the global mandate to adopt low emission oriented development and Indonesia’s RAN-
GRK, development of relevant technical performance and safety standards for LED products are
imperative. This would restrict the supply of sub-standard LED products in local markets.
4.4.2 Existing Standards for street lighting in Indonesia
The Standar Nasional Indonesia (SNI), which are the Indonesian National Standards, specify a range
of lighting standards. Most of the standards were developed based on the International Electrotechnical
Commission (IEC) standards. These standards are designed for general lighting, performance and
38
safety requirements pertaining to fluorescent lamps (single capped and double capped) and lamp control
gear. There is no exclusive standard for LED street lighting in Indonesia. SNI 7397: 2008 LED signal
lamps on trains has been adopted from IEC 7397. Ministry of Public Works (MPW) provides standards
on procurement and installation of street lights and has set a general standard for street lighting in 2005.
SNI 6197:2011 Energy Conservation in Lighting System requires 70 Lumen/W and 40,000 hour lifetime
for household LEDs.
The road classification and specification of street lighting for urban areas, including the luminance and
illuminance requirements are provided in SNI 7391, 2008. Indonesian standards 04-6959.1-2003 and
SNI 04-6959.2.3-2003 have been introduced for producers, importers and sellers of light control
equipment and AC electronic ballasts for fluorescent lamps.
All enterprises that produce, import and trade lamps must meet stipulated national standards of SNI 04-
6973.1-200512, SNI 04-6973.2.1-2005, SNI 04-6973.2.2-2005, SNI 04-6973.2.3-2005, SNI 04-6973.2.5-
2005 and have a certificate issued by accreditation institutions or laboratories. Article 91 of Industrial bill
criminalizes the non-compliance with mandatory SNI standards (Foreign market access report, 2010).
Once an SNI is stipulated as mandatory, the standard becomes a requirement of the market. Mandatory
SNIs are put in effect in a non-discriminatory manner which means that they are valid for both foreign
imported goods and domestically produced goods.
SNI 04 6973.2.3-2005 (Part 2.3 of Lamps: Special requirements for street lighting) standard specifies
the luminaire standard for other lamps but not for LEDs.
Further, a few local governments have come up with their own Technical procurement (technical
specification bid) documents for LED street lighting, including the Government of Gorontalo (Spesifikasi
Teknis Lampu Penerangan Jalan Umum, February 2010). These documents are not governed by any
specific standards approved by the National government and the specifications requirement in the bid
documents vary between provinces/cities which in turn could lead to quality, safety and performance
issues in the long run.
There is a lack of testing protocols to test LEDs for technical specifications. At present most of the
laboratories can test only incandescent lamps and self-ballasted lamps for general lighting. However,
lites.asia13 has come up with the “Test and Performance criteria for LEDs operating in tropical countries”.
The standards include Initial light output, Lumen maintenance, supply over voltage, supply under
voltage, accelerated temperature/humidity test, ingress protection, heat sink maintenance.
12 SNI 04 -6973.2.1-2005 (Part 1 of Lamps: General Requirements and Test)
SNI 04 -6973.2.1-2005 (Part 2.1 of Lamps; Special Requirements: Fixed General Lamps)
SNI 04 -6973.2.2-2005 (Part 2.2 of Lamps: Special Requirements of Embedded Lamps)
SNI 04 -6973.2.3-2005 (Part 2.3 of Lamps: Special Requirements of Street Lightening)
SNI 04 -6973.2.5-2005 (Part 2.5 of Lamps Special Requirements of Floodlight)
13 Lites.asia is a cooperative forum for countries in the Asia-pacific region focusing on lighting
39
4.4.3 Road Classification & Standards for Illumination
Roads in Indonesia are broadly classified into national roads, provincial roads and city/municipal roads.
National roads are arterial roads providing highway connection between provincial capitals and national
strategic roads and toll roads. Provincial roads are collector roads in the primary road system providing
connections between the provincial capital and municipal cities or towns and between district capitals in
a province and provincial strategic highways. City roads are public roads in a secondary road network
that provide connection between service centres and residential areas in a city (Indonesian commercial
newsletter, January 2012).
Classification of roads in Indonesia and specifications for street lighting in urban areas are provided in
SNI 7391 of 2008. The specification is as follows:
Table 14: Road classification and street lighting specifications in Indonesia
Type/Road
Classification
Illuminance Luminance
E average
(lux)
Uniformity L Average
(cd/m2)
Uniformity
g1 VD VI
Sidewalk / Footpath 1 – 4 0.10 0.10 0.40 0.50
Local Roads
- Primer
- Secondary
2 – 5
2 – 5
0.10
0.10
0.50
0.50
0.40
0.40
0.50
0.50
Collector Roads
- Primer
- Secondary
3 – 7
3 – 7
0.14
0.14
1.00
1.00
0.40
0.40
0.50
0.50
Arterial Roads
- Primer
- Secondary
11 – 20
11 – 20
0.14 – 0.20
0.14 – 0.20
1.50
1.50
0.40
0.40
0.50 0.70
0.50 0.70
Arterial Road with
controlled access,
freeway
15 – 20
0.14 – 0.20
1.50
0.40
0.50 0.70
Flyover,
interchange road,
tunnel
20 – 25
0.20
2.0
0.40
0.70
Key:
cd = Candela
g1 = Emin/Emax
VD = Lmin/Lmax
VI = Lmin/Laverage
TJ = Glare Limitation
40
Since India is a developing country with similarities to Indonesia in various respects, Indian classification
of roads and illumination standards are considered for comparison with Indonesian standards. The
classification of roads in Indonesia and the prescribed lighting requirements have been compared with
standards prescribed by the Bureau of Indian Standards (BIS). Table 15 indicates BIS standards for
levels of illumination for different road classifications. A comparison of the two standards indicates the
scope for further strengthening the Indonesian standard.
Table 15: Type of roads and levels of illumination based on Bureau of Indian Standards
Classification
of lighting
installations
Type of road Average level
of illumination
of road surface
(lux)
Ratio of
Minimum/
Average
Illumination
Type of luminaire
Preferred Permitted
Group A114 Important traffic
routes carrying
fast traffic
30 0.4
Cut-off15 Semi cut-off16
Group A217 Other main roads
carrying mixed
traffic, like main
city streets,
arterial roads,
throughways, etc.
15 0.4 Cut-off Semi cut-off
Group B118 Secondary roads
with considerable
traffic like
8 0.3 Cut-off Semi cut-off
14 Group A1: For very important routes with rapid and dense traffic where the only considerations are the safety and speed of the
traffic and the comfort of the drivers
15 Cut-off Luminaire: A luminaire whose light distribution is characterized by rapid reduction of luminous intensity in the region
between about 80o and the horizontal. The direction of maximum intensity may vary but should be below 65o. The principal
advantage of the cut off system is the reduction of glare.
16 Semi-cut off luminaire: A luminaire whose light distribution is characterized by a less severe reduction in the intensity in the
region of 80o to 90o. The direction of maximum intensity may vary but should be below 75º. The principal advantage of the semi-
cut off system is a greater flexibility in siting.
17 Group A2: For other main roads with considerable mixed traffic like main city streets, arterial roads and thoroughfares
18 Group B1: Secondary roads with considerable traffic like local traffic routes, shopping streets
41
local traffic routes,
shopping streets
Group B219 Secondary roads
with light traffic
4 0.3 Cut-off Semi cut-off
The key results of the analysis are as follows:
The roads are categorized based on the usage and purpose in both the countries
The prescribed illumination level for specific categories of roads is more or less in the same
range in both countries
The type of luminaire (namely cut-off & semi-cut-off) is not included in the Indonesian standards.
Cut-off luminaire allows less than 2.5% of light to leave the light fixture (above 90 degrees)
compared to 5% of light emitted by semi-cut off lights. The light emitted into the sky causes
glare and light pollution which has a significant effect on mood of human beings, animal life and
obstructs astronomical studies. To minimize the light pollution cut-off luminaire are preferred for
street lights.
4.4.4. International experience in defining LED street lighting standards
India also faced similar challenges due to the lack of LED street lighting standards earlier in 2009-10,
when local governments and private companies started adopting LED technology for street lighting. The
solution was that Standards prescribed by the American National Standards Institute (ANSI),
International Electrotechnical Commission (IEC) and Illumination Engineering Society (IES) were
adapted by India as temporary standards. A “Core team” consisting of major ministries and regulatory
bodies including Ministry of Power, Bureau of Energy Efficiency, Ministry of New & Renewable Energy
and Department of Information Technology was constituted to define this draft standard. A resolution
was passed at the national level to promote LED lighting in a phased manner over a fixed time period.
Accordingly, Bureau of Indian Standards was directed to come up with Indian version of standards for
LEDs based on the available International standards. As a result of the determined effort, BIS defined
LED street lighting standards for India in the year 2012. Local governments in India utilise these
standards to prepare technical bids for installation of LED street lighting.
The key standards developed by BIS, based on international standards are as follows:
IS 16101: 2012 General Lighting; LEDs and LED modules; Terms and definitions
IS 16102(Part 1) 2012 Self ballasted LED; Lamps for General Lighting Services Part 1 Safety
Requirements
IS 16102(Part 2): 2012 Self-Ballasted LED; Lamps for General Lighting Services Part 2
Performance Requirements
IS 16103(Part 1): 2012 LED Modules for General Lighting; Safety Requirements
IS 16103(Part 2): 2012 LED Modules for General Lighting; Performance Requirements
19 Group B2: Secondary roads with light traffic
42
IS 15885(Part 2/Sec 13): 2012 Lamp Control Gear Part 2 Particular Requirements Section 13 d.c. or
a.c. Supplied Electronic Controlgear for LEDed Modules
IS 16104: 2012 d.c. or a.c. Supplied Electronic Control Gear for LED Modules;
Performance Requirements
IS 16105: 2012 Method of Measurement of Lumen Maintenance of Solid State Light
(LED) sources
IS 16106: 2012 Method of Electrical and Photometric Measurements of Solid State
Lighting (LED) products
IS 16107: 2012 (Part 1) Luminaires performance; General requirements
IS 16107: 2012 (Part 2) Luminaires performance; Particular requirements section 1 LED
luminaire
IS 16108: 2012 Photobiological safety of Lamps and Lamp Systems
A detailed list of IEC published LED lighting standards are provided in Annexure 1.
Minimum performance standards for LED street lighting in India
Minimum performance standards in India have evolved over time and are defined and governed by the
BIS. BIS standards are referred to by Indian cities for the procurement of LEDs and could be adapted
by the Indonesian government at a National level. Typical specifications used by Indian local authorities,
based on BIS guidance are listed below (Table 16). These specifications could guide the development
of Indonesian standards on LEDs.
Table 16: Indicative product specification for LED lighting 20
Parameters Value
Luminous efficacy ≥ 95 lm/W
Operative voltage range 140 – 270 V
Operating voltage 230 V ± 10%
LED operating frequency ≥ 120 Hz
Input supply frequency 50 Hz ± 3
Total harmonic distortion Current <10%; voltage
<3%
Correlated Colour Temperature 6,000 – 6,500 ˚K
Rated Colour Rendering Index 75 (minimum)
Power Factor ≥ 0.90
Operating current ≤ 700 mA
Beam angle (LED) 120˚ minimum
Uniformity ratio (Emin/Eavg) 40%
20 Source: Technical specification requirements adopted by Indian cities based on BIS
43
Other indicative parameters to be considered in a performance standard for LED lamps:
- LED module/ array shall deliver at least 70% of the initial value of lumen output after 50,000
hours of operation.
- Life span of LED source including its driver shall be minimum of 50,000 hours
- The P/N junction temperature of individual LED must not exceed 70°C
- LED should have thermal resistance junction to solder point is < 5°C/W
- LED junction temperature should be 150°C. ± 5°C
4.4.5. Developing standards for LED lighting in Indonesia
Agencies involved in the development of LED standards
National Standardisation Agency of Indonesia (BSN) is responsible for the legalisation of Indonesian
National Standards (SNI). Technical committees and technical sub-committees to draft standards. must
be developed and formalised by BSN.
MPW procures all materials related to national roads and is the lead agency for setting standards on
luminance on road surfaces, minimum distance of lighting poles and lifetime of lamps, an approval from
MPW is required for installing lighting products on national roads.
Ministry of Transport is responsible for the development of safety standards for street lighting and the
replacement of lighting units on national roads.
Ministry of Industry is responsible for setting standards for all goods including lighting products and
support the development of technology performance standards for street lights.
There are 27 committees for product standardization, with each lead ministry defining the membership
(producers, consumers, test labs, experts). So far, there is only one committee which addresses both
electronic household appliances and lighting.
The Ministry of Trade (MoT) monitors products on the market. If deficient products are found, the
producer is required to upgrade its facilities within six months. MoT ensures that all enterprises comply
with the Indonesian national standards for manufacturing, exporting and trading. Producers are required
to undergo an ISO audit and test of a sample before they are certified that they fulfil the SNI standard.
Importers are required to furnish proof of a similar check; however, this is rarely verified. Approximately
60 auditors are involved in conducting spot checks of production in the country.
Typically Indonesian standards in the field of electronics are only set after an IEC standard has been
defined. There are no Indonesian standards for major street lighting technologies including LED and
induction lamps. It is envisaged that the MoI will not propose a product standard for LED lighting, unless
such a specification is issued by the IEC. Standards for technical performance and safety for street
lighting are developed by Streets and Bridges R&D Agency (“Puslitbang”) of MPW. Puslitbang has been
asked to review the existing safety and performance standard and also add specific standards for LED
44
street lighting. However, Puslitbang will review the standards only after receiving an official request from
Directorate General of Bina Marga (Highway), MPW.
National standards development process in Indonesia
The Agency of National Standard (“BSN”) was established under the Regulation of Government No. 102
of 2000 about National Standardization.
Standards are typically established via two main approaches:
Consensus based i.e. all the stakeholders involved agree with the draft of the standard; and
Scientific evidence based
The standard setting process of the BSN is given in the Figure 6 below.
Figure 6: Standard setting process of BSN
Formulation of a standard involves the following sequential steps:
Responsibility: BSN
Publication of proposed plan
Drafting plan
Responsibility: SC/Sub-SC
Standard Draft 1 (RSNI1)
Responsibility: SC
Standard Draft 2 (RSNI2)
Responsibility: SC
Responsibility: BSN
2/3 voting
Less than 2/3 voting Verification
Establishment/ Publication
Responsibility: BSN
Standard Draft 3 (RSNI3)
Responsibility: SC by Consensus
Voting
Responsibility: MASTAN
45
Planning of National Program for Standard Development (“PNPS”): Towards the middle of
fiscal year, BSN publishes the proposed plan for PNPS for the next year. Based on the plan,
appropriate Steering Committees (SC) or sub-SCs are constituted to draft the plan. The
committees will develop and decide the PNPS draft. The draft plan is then submitted to BSN for
approval in the month of February in the subsequent year.
Development of Standard Draft 1 (“RSNI1”); Time period - 3 months: The SC empanels a
drafter(s) to formulate RSNI1
Development of Standard Draft 2 (“RSNI2”); Time period - 3 months: The SC deliberates on
the formulated RSNI1; inputs from all members are sourced. Where necessary, relevant
stakeholders deemed are invited to provide specific inputs.
Development of Standard Draft 3 (“RSNI3”); Time period - 3 months:
The SC conducts a consensus meeting between all members and experts for additional inputs
to the draft; RSNI3 is finalized based on the collective decision of the SC.
Enquiry: Draft of RSNI3 is submitted to BSN for approval. The documents are published by
BSN and circulated to all SC members and members of the standardization community. If 2/3rd
of the voting members agree to the circulated draft, RSNI3 will be used as RSNI (final draft of
standard). If not accepted, RSNI2 is further checked and an improved RSNI3 is prepared by the
SC.
Establishment of standard; Time period - 1 month
Publication of standard; Time period - 1 month
Committees serve for about 3-year period and usually meet three times before a consensus is
established on the standard, which is communicated to the Indonesian standards institution BSN, which
then issues a standard under SNI.
Steering Committee of BSN
BSN is responsible for standards development and it draws on technical committees and technical sub-
committees from the relevant ministries to draft a standard. MoI and MoT are responsible for submitting
proposals to BSN for the development of safety standards and technology performance standards for
street lighting respectively. After submitting the proposals for standards development, a steering
committee (SC) and a sub-SC would be formed. Establishment of SC can be initiated by a technical
agency (ministries), stakeholders or BSN.
Composition of SC: Typically, the SC constitutes the chairman/vice chairman (if relevant), secretary and
members. In case the chairman has no technical capabilities, a vice chairman is nominated, with
relevant experience and expertise. Chairman is usually appointed for 3 years and can be extended for
3 years. A minimum of 9 members would constitute the team. The chairman is required to hold at least
a bachelor degree with 2 years of experience on relevant scope of work. Members of the SC should be
drawn from regulators, producers, consumers and experts. Members should hold at least a diploma
degree with minimum 3 years of expertise or 10 years of experience for senior high school degree.
46
Establishment of sub-SC is in accordance with the scope of work. In cases where the scope of work is
too wide, the SC can develop sub-SCs with specific scopes of work.
The Standardisation Society of Indonesia (MASTAN) is an independent non-profit organisation
consisting of nearly 3000 members representing regulators, industry, consumers, infrastructure,
institutions and experts. MASTAN facilitates the consultation and e-ballot voting processes during the
SNA development stages.
4.4.6 Lessons from international standards setting process
The typical process flow for setting standards in India is summarised here for the purpose of comparing
it with the process followed in Indonesia. The Indian standardization process entails formation of a
balanced technical committee; consultations with concerned stakeholders, seeking comments from
public before finalization. The principles of consensus along with World Trade Organization/Technical
Barriers to Trade (WTO/TBT) principles are also being followed during preparation of the standards.
The formation of the technical committee is crucial to the standard setting process. The typical
composition of the standard committee includes the Chairman (independent body), member secretary
(BIS), manufacturers, laboratories/R&D institutions, Government & regulatory bodies, consumer/user
organizations, industry associations, public sector units, consulting firms and professional & academic
bodies.
The standard setting process of the BIS is given in the Figure 7 below:
Figure 7: Standard setting process of BIS
Approval of new subject by National committee
Circulation to members of national committee for comments
Draft standard in wide circulation for public comments
Approval of draft standard by consensus
Preparation of preliminary draft standard
Discussion on the draft standard and comments by the members of the technical committee
Discussion by the national committee
Publication of standards
47
4.4.7. Enhancing technical capacity of institutions developing standards on performance and safety
Typically, only selected members from MoI and MoT would be part of the Steering Committees which
are set up to define new standards. To further strengthen the technical capacity of the ministries, Other
Working Groups (OWGs) could be introduced internally within a Ministry.
Formation of Other Working Groups (OWG) under MoI and MoT:
OWG members: Representatives from the following sectors are probable members who could
constitute OWGs: Industrial associations, Ministry of Trade, lighting industries
(manufacturers/suppliers), Non-profit organizations, educational institutions, research
organizations, sector experts, etc.
Role of OWGs: OWGs make efforts to draft or outline proposals for the development of
standards, which are to be submitted to BSN for consideration. OWGs shall follow a definitive
procedure (to be defined by the Ministries) and would be involved in data collection, surveys,
market assessment, stakeholder consultation (including consumers) and periodic requirement
assessment to inform the overall standardization process. The members of OWGs would work
as a team and take decisions by participatory approach. OWSs will provide technical support
by providing all the necessary information to the respective ministry.
Observing members: OWG members shall be part of the standards preparation process of
BSN and could be given an observer status, without voting rights. However, the comments
raised by the group should be addressed by the SC. This would provide an opportunity to
register the comments of a wider section of the society. BSN shall be requested to provide
observer status to OWG of individual ministries.
Strengthening the standard setting process adopted by BSN:
The standard setting process should include a wide range of stakeholders including
professionals & academic bodies, manufacturers, laboratories, Research & Development
institutions, regulatory bodies, industry associations, public sector units, consulting firms, end
users and citizen groups.
The draft standards prepared by BSN should be widely circulated to the public (also through
stakeholder meetings) to seek inputs and suggestions. Draft standards could also be published
online to receive comments.
The overall educational qualification and experience requirement of the SC members should be
raised in consultation with relevant stakeholders.
Observer status should be provided to OWG (proposed under MoI and MoT) to enable greater
stakeholder participation in and contribution to the standard setting process.
48
4.4.8. Barriers/challenges
Use of low standard products - Due to the price differential between standard and sub
standard LEDs of a factor of 2 – which then are still 2.5 times as expensive as conventional
street lighting, many Indonesian cities tend to prefer the low standard products. Those however
often face problems with heat management; some experience reduction of lumen output up to
50% after 6-12 months. This situation in turn is discouraging the users to choose LED products
for street lighting.
Lack of IEC standard for LED Street lighting - lack of an IEC product specification for LED
street lighting is hampering the development of Indonesian version of product standards. While
IEC has come up with Performance and Safety (PAS) standards for street lighting, the review
of these standards for LED is yet to commence. The review is expected to be completed by
2014.
MoI confirmed that it wants to wait with a LED standard until corresponding IEC
standards have been finalized21 - Product standard SNI 2008 is purely voluntary. Provincial
and municipal roads are not covered by any standard.
Indonesia lacks training protocol for LEDs, laboratory facilities (including accreditation) and
trained operators. There is a need to upgrade laboratory capabilities to test LED standards.
4.4.9. Recommendations
Consensus is required from the relevant ministries including MEMR, MoI, MPW and MoT
together with BSN to adopt the existing international standards (including IEC and IES
standards) or standards from similar Asian countries, such as India. The TSU to be established
with the international NAMA support funding should play the role of a facilitator and provide
technical support during the setting of a national standard for LEDs in Indonesia.
SNI 4 6973.2.3-2005 (Part 2.3 of Lamps: Special requirements of street lighting) specifies the
luminaire standard for lamps but not including LED. Solid state lighting (i.e. LED) therefore
should be added as addendum to this standard.
Standards for technical performance and safety for street lighting are developed by Streets and
Bridges R&D Agency (“Puslitbang”) MPW. Directorate General of Bina Marga (Highway) could
request Puslitbang to review the existing safety and performance standards and add specific
standards for LED street lighting.
As an alternate temporary arrangement, a detailed technical specification document on LED
street lighting procurement for all kinds of roads could be developed by relevant Ministry. The
technical document could be developed considering the existing Indonesian LED street lighting
standards and other International standards. This document could then be circulated to all the
21 Interview with MoI in July 2013.
49
Indonesian cities through the provincial government and the cities could be directed to use it.
Publications and training materials (including on-line versions) together with articles and
advertisements could also be released on street lighting (including LED standards, general best
lighting practices, etc.) for local governments.
Testing protocols, infrastructure and accredited laboratories must be set up to ensure testing of
LEDs for compliance to the technical standards. As a first step appropriate laboratories should
be identified across Indonesia, or national Government should build one, and the laboratories
should be equipped with facilities and accredited for testing new requirements arising as a result
of adapting international standards. There are some testing laboratories in Indonesia, for
example in Surabaya, which can be upgraded with more facilities to test LED performance and
safety.
After adapting suitable standards, all suppliers and manufacturers whose products comply with
technical requirements (prescribed by Indonesian standards and other International standards)
of LED street lighting, could be listed in the Ministry of Energy & Mineral Resources and other
relevant government websites. Local governments shall be directed to procure LED lights only
from identified and tested companies. This action would protect users from cheap and non-
quality products.
Given the substantial problems with the lack of National LED standardization, other lighting
technologies such as induction lamps could also be considered by the NAMA, especially if their
performance is more stable. The technology suitability assessment should be carried out in
individual cities to choose the most suitable energy efficient lighting options (may be more than
one per city, depending on the baseline situation).
4.5. Financing options for efficient street lighting
4.5.1 Overview of resource needs for the SSLI NAMA.
In this section an estimated budget for the SSLI NAMA has been developed based on different
implementation scenarios. The costs associated with the implementation of the SSLI NAMA include:
Capital investment in the LED technology (or alternative efficient lighting technologies)
Capital investment in metering devices
Set-up of institutional infrastructure (in particular, the set-up of the TSU see Section 4.1.3)
Human resources (in particular, installation and maintenance staffing costs at the city level)
Capacity building costs (technical training related to technology installation and maintenance,
awareness raising at municipal level, noting that the TSU will do much of this work).
50
As capital investment for SSL technology is the main cost driver, an overview of the basic technical and
financial parameters is provided below using the same format as outlined for the baseline determination.
The emissions related elements such as the GEF are equal to what has already been defined for the
baseline.
Technical project scenario parameters
The key technical parameters for the project scenarios are the wattage of the installed lamps and the
typical lifetime of the lamps. While individual cities will logically be free to determine the appropriate
efficient lighting technology/-ies to suit their circumstances, for this analysis it is assumed that the
introduced technology is LEDs that are available with different wattages. Similarly, in practice, cities
joining the SSLI NAMA will most likely assess the specific lighting requirements as part of an overall
“design-based street lighting system”, which is a combination of wattage and type of lamp, pole height
and spacing to meet national standards and so on. Cities will logically work with suppliers and ESCOs
to design a system which is optimal for their specific circumstances. For simplicity, in our analysis
average wattage levels of LEDs replacing equivalent (typically mercury or sodium lights) are applied for
an overall assessment at the NAMA concept stage. Hereby we assume that both 150W and 250W HPS
lamps as well as 250 W Mercury lamps are both replaced with 140W LEDs.
Table 17: Technical parameters
Parameter Truncated mean* baseline value Wattage per lamp 140 Operation hours per day 12 Typical lifetime of average lamp (in hours) 50,000
*) Truncated mean is the average of a number of values discarding the highest and lowest value
Source: Assessment of seven Indonesian cities, based on GIZ PAKLIM (2012)
Financial project scenario parameters
The following Table 18 lists key financial elements relating to the installation of energy efficient lighting.
Among these are typical costs per lamp, related civil works and O&M. Again the values are based on
the assumption that LED technology is applied.
Table 18: Financial parameters
Parameter Baseline value
Costs per average LED lamp (110W) ~601 USD
Civil work costs per lamp 19 USD
Additional contingency assumption per lamp
(might cover additional costs for housing
and cabling that has to be replaced in some
cases as well)
30% of LED and civil work costs (~190 USD)
51
O&M costs per lamp and year 2 USD (2.4 USD from year 3 onwards)
PIP loan interest rate 5%
ESCO model hurdle rate 10%
Financial market interest rate 12%
Source: Assessment of seven Indonesian cities, based on GIZ PAKLIM (2012)
The resource needs are estimated below for different scenarios involving different levels of ambition in
the number of cities to be covered under the SSL NAMA, and hence different volumes of lamps to be
installed. GIZ foresees three phases from 2014 to 2019: A demonstration phase, a scaling-up phase
and finally the transformation phase. In the context of these three phases two pathways are assessed,
a conservative pathway based on a slower expansion rate for each of the three phases and an ambitious
pathway based on a more ambitious expansion rate for each of the three phases. An overview of these
is provided in the Figure 8 below.
Figure 8: Phases and scenarios for efficient street lighting implementation
Below (Table 19) is an overview of the cities that are considered in the analysis under each of the
pathways.
Table 19: Overview of SSL NAMA Implementation Phases and Scenarios for analysis
Phase Timeframe Relevant
pathway
New
cities
added
Total
no. of
cities
Cities covered (sum)
Phase I Start 2014 to mid
2015
Scenario I
(conservative)
2 2 Yogyakarta, Makassar
Scenario II
(ambitious)
4 4 Yogyakarta, Makassar,
Probolinggo,
Pekalongan
Phase 1 (2014/2015)
Demonstration
Phase 2 (2015/2016)
Scaling-up
Phase 3(2017-2019)
Transformation
Conservative Pathway
SSL for 2 citiesSSL for 2
additional citiesSSL for 5
additional cities
Ambitious Pathway
SSL for 4 citiesSSL for 8
additional citiesSSL for 10
additional cities
52
Phase II Mid 2015 to end 2016 Scenario III
(conservative)
2 4 Yogyakarta,
Pekalongan, Makassar,
Probolinggo
Scenario IV
(ambitious)
8 12 Yogyakarta,
Pekalongan, Makassar,
Probolinggo, Surakarta,
Blitar, Malang,
Semarang, Salatiga,
Medan, Manado,
Mojokerto
Phase III Start 2017 to end 2019 Scenario V
(conservative)
5 9 Yogyakarta,
Pekalongan, Makassar,
Probolinggo
+ 5 additional cities
Scenario VI
(ambitious)
10 22 Yogyakarta,
Pekalongan, Makassar,
Probolinggo, Surakarta,
Blitar, Malang,
Semarang, Salatiga,
Medan, Manado,
Mojokerto
+10 additional cities
An estimation of resource needs is directly linked to the number of installed LEDs. The following Table
20 describes the number of required lamps for each phase of the two pathways and estimates the
resources needed for installation of LED technology.
Table 20: Cumulative number of lamps and resource needs for the two pathways
Phase I Phase II Phase III
Conservative
pathway
Number of lamps
34,000
65,690
191,232
Estimated
installation costs
(1000s USD)
27,553
53,235
154,974
Ambitious
pathway
Number of lamps
65,690
266,557
517,640
53
Estimated
installation costs
(1000s USD)
53,235
216,017
419,495
Source: Own calculation based on scenarios defined by GIZ
Overall the number of lamps accumulates from about 34,000 to more than 190,000 under the
conservative scenario. The costs respectively increase from about 27.5 million USD for phase I to almost
155 million USD in phase III.
Under the ambitious pathway more than 500,000 efficient lamps are installed in phase III at
costs of almost 420 million USD. Both pathways are illustrated in
Figure 9.
Figure 9: Estimated number of replaced lamps under the two pathways
Source: Own calculation based on scenarios defined by GIZ
4.5.2 Methodological approach for calculation of cash flows for baseline and project scenario
The costs outlined in Section 4.5.1 will be recovered through the reduced costs of electricity
consumption, maintenance and retrofits compared with the baseline scenario involving conventional
lighting technologies.
Table 21 below summarises the parameters included in the financial analysis of the SSL NAMA,
including the baseline values (“Value baseline”) and the adjusted parameters for the SSL NAMA
implementation scenario (“Value SSL NAMA”).
Table 21: Parameters included in financial analysis of SSL NAMA
54
Lamp Data Value
baseline Value SSL
NAMA Unit Source/comment
HPS lamps
Watts level 150 95 Watts Own calculation based on
GIZ PAKLIM, p.45
Typical lifetime 24,000 50,000 hours GIZ PAKLIM, p.8
Costs per lamp 246 601 USD OSRAM
Mercury vapour lamps Watts level 250 159 Watts GIZ PAKLIM, p.45
Typical lifetime 24,000 50,000 hours GIZ PAKLIM, p.8
Costs per lamp 226 601 USD GIZ PAKLIM, p.45
Operational Expenditures (OPEX) Value
baseline Value SSL
NAMA Unit Source
Operation hours per year 4,380 4,380 hours / a Assuming 12 hours of operation
a day
Electricity tariff 75 USD22 75 USD
Average electricity tariff of assessed cities (might deviate
according to city)
Electricity tariff increase (per year) 2% 2% Own assumption
T & D losses 10% 10% Default value from CDM meth Overall O&M costs per lamp within year 1-3 6.7 2.0
USD / lamp ICLEI
Overall O&M costs per lamp within year 3-> 8.0 2.4
USD / lamp
Own assumption that O&M costs increase after 3 years by
20% NAMA specific costs (administration, monitoring etc.) 0 25,000
USD / year Own assumption
Revenue Specific Data Value
baseline Value SSL
NAMA Unit Source
Streetlighting tax level 7.00% 7.00% %
Average tax level according to information on 7 cities, plus the
16 cities in long list Decreased energy consumption due to metering 40% 40% %/a
Only valid when power meters are applied
Metering costs Value
baseline Value SSL
NAMA Unit Source
3 phase electricity supply 1,500 1,500 USD / meter PLN (includes installation costs
- civil works)
Number of lamps that can be covered by meter 25 25
lamps /meter
Metering annual cost 10 10 USD / a Own assumption
Lifetime of metering equipment 10 21 21 years Own assumption
Source: Spreadsheet “Investment-Analysis – Assumptions” by Perspectives based on sources listed in table
The financial model developed for the SSL NAMA produces the following outputs:
Cash flow analysis for the SSL NAMA scenario in comparison to the baseline; including the
expenses and revenues schedule over the SSL lifetime (approximately 50,000 operation hours).
Both for the conservative and ambitious pathway.
Net Present Value (NPV) for the SSL NAMA scenario. Both for the conservative and ambitious
pathway.
Illustration of financing sources applied for coverage of incremental installation costs. Both for
the conservative and ambitious pathway.
22 The tariff assumed for modeling purposes is lower than the regulated tariff in 2013, which is ca. 90 USD. This was done to
avoid over-estimating the cities’ energy bills on the basis of uncertain lamp data, which include a high share of illegal connections.
It would be misleading to apply the regulated tariff to all of the installed lamps and calculate payback on this basis.
55
The results of this analysis are presented below in section 4.5.5.
4.5.3 Identification of funding sources
While the replacement of conventional lighting with LEDs or other efficient technologies will logically pay
off as a result of energy savings over time, the key barrier to uptake is that municipalities do not have
sufficient funds to cover the up-front capital and installation costs. The municipal governments
interviewed during the research undertaken for this report generally indicated that their efficient lighting
replacement programmes are therefore taking place at a rather slow pace, with small-scale replacement
of conventional lighting with efficient lighting happening when replacement is due to take place anyway.
As loans are typically available for municipal governments at rather high interest rates of 12-15%, this
makes the option of borrowing to fund a more large-scale replacement programme generally
unattractive. Hence other funding sources are required to enable the SSL NAMA to reach scale over
the timeframe to 2020, and these are considered below.
Revenues from reduced PLN electricity bill after metering
Experience to date suggests that if metering is introduced, municipal street lighting electricity bills could
fall by 30-40% due to the tendency for overestimating energy consumption; in the case of Yogyakarta
the energy bill even fell by 60%. Assuming that the city’s street lighting tax is kept constant, the extra
revenue could be used to finance the introduction of efficient street lighting, with the electricity bill
savings generated by the efficient lights again reinvested in new efficient lights or used to cover the
initial costs of the metering roll-out. The drawback is that this financing option is only available to cities
that have not yet introduced metering, and that the introduction of the efficient street lights through such
a de facto revolving fund approach takes time. For example, savings of 1 MWh/year and lamp through
metering as achieved in Yogyakarta and calculating with a tariff of 0.075 USD/kWh would mobilize 75
USD/lamp, which means that financing of the meter itself would be achieved after one year of operation
(not including meter installation costs). Financing the entire cost differential between a high performance
LED and conventional street lighting would require a decade. This option is therefore only feasible when
considered in conjunction with other options.
From the point of view of implementing the SSL NAMA, metering should be seen as a top-order policy
priority and could form part of the unilateral NAMA component. It would enable other financing sources
to be unlocked (including from the municipal budgets). However, it is not seen as appropriate for funding
support be raised from donors to finance the metering roll-out, since the primary purpose of international
NAMA support is to support emissions reductions actions. Metering in itself does not save energy or
reduce emissions, but rather it helps provincial and municipal governments save money. As a result of
this, it can create the incentive for local governments to invest in energy efficiency activities. The finance
options considered here can then help stimulate such investment.
Street lighting tax increase
56
In cities which have set the street lighting energy consumption tax still below the 10% threshold (e.g.
Malang, where it is currently 7%), a temporary tax increase could create a funding source to cover the
investment costs, with the possibility to reduce the tax again once the installation is complete and
efficiency gains are being generated (GIZ PAKLIM, 2012a, p. 19). This could be politically difficult,
though, as usually the parliament only allows a tax increase when the PJU street lighting bill (lump sum
payment to PLN) is larger than the revenues from the tax. This option cannot be applied across the
board for political reasons (unpopularity of tax increases). Further, there is no direct hypothecation
between the tax revenues and the street lighting budget of the PJU, so it is unclear whether the funds
would in fact be allocated for efficient lighting. Therefore this option is also to be considered in
conjunction with other financing options.
ICCTF grant
The ICCTF is an ideally suited vehicle for the channelling of international sources of finance towards
climate mitigation projects in Indonesia, including in the energy sector, which is one of the priority
windows of the fund. As the existing funds are fully allocated, however, the ICCTF must be replenished
with new sources of finance. This could be achieved utilising NAMA facility funds for example, with the
ICCTF acting as the trustee/manager of the grant funding provided by the German/UK Governments,
and potentially other donors wishing to join the SSLI NAMA. The ICCTF is thus considered as part of
the financing roadmap in conjunction with the NAMA facility funding.
NAMA facility grant
In December 2012 the German and UK Governments jointly launched the NAMA facility – a support
fund of 70m EUR (95m USD) designed to support developing countries that show strong leadership on
tackling climate change and want to implement transformational NAMAs (BMU, DECC, 2012). The first
round of the NAMA facility was opened between July and September 2013, and a stage-one NAMA
Support Project Outline was submitted by MEMR in application for support funding for the SSL NAMA.
The facility will focus primarily on the mobilization of capital investments, but also offer support in the
form of technical assistance (TA). Financial instruments will include grant-based support instruments as
well as concessional loans. The selection of a specific financial instrument, including the interest rates
of subsidized loans, and the amount of funding provided through the Facility will be decided in the
context of each individual NAMA support project (German Government, 2013).
Projects selected in stage-one (NAMA Support Project Outline) will enter a second evaluation stage,
where full project feasibility studies will be carried out and then considered by the Facility Board. An
initial assessment of the suitability of the SSLI NAMA to the NAMA facility is provided in Section 5.1.
This financing option is seen as particularly relevant for financing the initial capital investment and TA
components of the SSLI NAMA implementation.
Carbon Markets
International carbon markets could provide a source of finance if the SSLI were registered under the
Clean Development Mechanism (CDM) instead of being financed as a NAMA. However, at current CER
prices, which are below 1 USD/tonne on the spot market, the revenues that could be earned from
monetizing emissions reductions alone would be highly unlikely to finance the planned lighting
57
replacement. At present, the outlook for the CER market is very weak until at least 2020, and possibly
beyond, because of the massive oversupply in the EU ETS, estimated at up to 2 billion allowances,
which is the main source of demand for CERs. Prices are essentially reflective of the cost of issuance –
at a certain price it becomes uneconomic to pay the transaction costs involved in verification and
issuance of credits. Price projections to 2020 are in the order of 2-3 USD/t at best. At current prices of
1 USD/t or less, the total emissions reductions estimated for the SSL NAMA would only raise around
100-400,000 USD if sold on the spot CER market23. Thus, CERs are not seen as a relevant source of
financing for the SSL initiative.
Other crediting mechanisms including NMM and the Japanese BOCM could theoretically provide longer
term monetization options for initiatives such as the SSL initiative. Where NMM is concerned, however,
there is still no agreed international framework within the context of the UNFCCC, no modalities for the
design and implementation of such a mechanism, and at the time of writing no pilots have been
announced or implemented anywhere in the world24. Outside of the UNFCCC framework, the EU ETS
regulatory framework allows for recognition of bilateral agreements between the EU and countries
implementing sector-based approaches, such as NMM. However, there is no certainty whatsoever on
the prices that would be paid for credits generated from an initiative implemented under this framework,
nor the volumes that would be accepted (if any). The Japanese BOCM is still being operationalised and
no projects have yet been implemented, with limited details available on eligibility, likely credit prices,
procedures for registration etc. Both of these sources are thus seen as highly uncertain at this stage,
and are not considered relevant given the intention to implement the SSL initiative within the next 5-7
years.
PIP loans
Concessional loans are offered by the Indonesian Investment Agency (PIP), administered by the MoF.
In total, PIP loans include assets under management with a volume of 1.9 billion USD in 2012 (PIP,
2012). According to meetings with PIP in July 2013, approximately 2.8m USD is available in 2013 for
energy efficiency activities, and for the following two years the plan is to invest 15-20m USD into public
sector energy efficiency activities (including street lighting and waste to energy). The “mandatory” loans
offered by PIP, with interest rates typically in the order of 5%, have the potential to be a key domestic
source of finance for the implementation of the SSL NAMA. PIP loans can help demonstrate the benefits
of the SSL NAMA in the initial pilot cities that would be co-financed with international funding support,
and then used to scale-up the NAMA over time.
Some challenges exist. Firstly, there is a lack of experience in the sector since PIP has so far not
disbursed significant loans for energy efficiency and renewable energy projects – most of its experience
is with major infrastructure such as hospitals, roads etc. Secondly, there is a perceived need from the
cities for streamlining the somewhat complicated and bureaucratic approval requirements. Supporting
23 Prices in the primary CER market (not yet issued CERs) tend to be even lower.
24 However, it can be noted that the design of a number of pilots is underway at present, funded by the German BMU.
58
the municipal governments in their PIP loan applications is seen as an appropriate task for the TSU to
be set up as part of the NAMA. This option is thus considered in as part of a package in conjunction with
NAMA facility funding channelled through the ICCTF.
Ministry of Finance initiatives on energy efficiency
The Fiscal Policy Office of MoF is considering the design and introduction of a new scheme to support
private sector ESCOs in implementation of energy efficiency. The draft concept at this stage is to
establish a revolving fund of 50 million USD to support energy efficiency implementation (maximum 5
million USD per project) with concessional lending rates. The main drawback is that it is very early stage
of development, and the earliest the new scheme might be available is the second half of 2014.
Depending on how the proposal develops, this option could form part of the package of options for
scaling-up the NAMA over time beyond the demonstration phase in 2014-15.
Unlocking unspent budget from line ministries
There is the theoretical potential for re-allocations within the national budget to unlock unspent revenues.
For example, according to MoF (2012, p. 23) MoT only spend 10-30% of its budget in recent years,
while MPW spending reached 70-80% of budget. These unspent funds could in theory be used for
investing in a range of energy efficiency activities, including street lighting efficiency. The key challenge
is that MEMR does not have any power to direct other line ministries in this way and there is no basis
for MoF to do so. Due to these difficulties, this option is not considered to be realistic at this stage.
Special Allocation Fund (DAK) for Emission Reduction grant
DAK is defined as “a fund that is originated from the national budget that is allocated to specific regions
in order to help fund specific activities that are under regional authority and in line with national priorities”
(Jakarta Post, 2012). Primarily, the funds are intended to help less advanced regions by financing
activities of national priority, for example in education, health and infrastructure. Street lighting is not
included in the list of national priorities for 2014. In future years, the national government would need to
identify and define street lighting as a priority sector and identify the specific regions which should be
targeted for such grants. In order for grants to be allocated under the DAK for emission reductions, the
Coordinating Ministry for the Economy would be required to direct MEMR to set targets and objectives
for street lighting efficiency improvements. This process would require very high level political
engagement and would be likely to take considerable time and effort, with uncertain outcomes and
timeframes. The DAK grant is therefore not seen as a likely option for the demonstration phase of the
SSL initiative which is intended to start in 2014. It may become a realistic option for certain cities in
disadvantaged regions over the longer term.
Electricity pricing reform
Indonesia’s subsidised cost of electricity reduces the incentive for municipal governments to invest in
efficient street lighting. In theory, regulatory reform could serve to increase electricity prices to cost-
59
reflective levels. However, as discussed in Section 4.2, major electricity pricing reform has been shown
to be politically sensitive and is highly unlikely in the lead up to the 2014 presidential election. This option
is thus misaligned with the intended timing of the SSL NAMA implementation. It may become relevant
as part of the scaling-up phase of the NAMA beyond 2015.
ESCO models
While still at an infant stage in Indonesia, an expansion of the ESCO industry could be a way of unlocking
cost savings for local municipalities, but would likely need to be supported in combination with sources
of public finance and policy reform. Currently, there is a lack of regulatory framework Local Government
Regulation in place (Peraturan Daerah) in place to enable ESCO contracting. With the necessary
regulatory framework, this option is could support the scaling-up of the street lighting investment when
combined with some of the other promising financing options. Exhibit 1 provides more detail on the
ESCO model and the experience in Indonesia and India with ESCOs.
60
Exhibit 1: ESCOs
Energy Services Companies, or ESCOs, deliver energy efficiency savings in return for a payment which is
financed through the cost reductions associated with those savings. ESCOs can be either state-owned or
privately owned. One of the largest Indonesian ESCOs, PT. Energy Management Indonesia is a state-owned
corporation with annual turnover of ca. 3m USD (PT Energy Management Indonesia, 2007). In the context of the
SSL NAMA, a privately owned ESCO would enter into a performance contracting arrangement with the local
government, provided that the regulatory framework allows for this. Payment for the services performed by the
ESCO is then made either ex-ante or ex-post, or more likely a mix of both, which is when the ESCO requires a
down-payment covering part of the cost.
- Ex-ante payment. The local government pays the ESCO up front to undertake the street lighting replacement
and then recovers the cost of this through reduced energy bills.
- Ex-post payment. The energy savings are guaranteed by the ESCO, which then obtains finance (e.g. by
going to a bank to get a loan, or raising finance on the capital markets) and performs the services. The
ESCO is paid by the local government through the cost savings that are generated.
ESCO experiences in Indonesia
So far the experience with ESCOs in Indonesia has been rather limited – in particular with regards to street
lighting. The barriers include the lack of experienced ESCOs (GIZ PAKLIM, 2012a) and the heavy subsidisation
of electricity prices, which reduces the incentive on large consumers to seek out and pay for energy efficiency
improvement opportunities. Where local government contracting of ESCOs is concerned, perhaps the biggest
barrier is the existing anti-corruption regulations, which prevent the sharing of municipal street lighting tax
revenues with the private sector.
One example of a successful ESCO arrangement in Indonesia involves the optimisation of street lighting in the
city of Pasuruan. In 2003-2008, the company PT Fokus Indo Lighting provided the municipal government with a
package of services involving the complete reconfiguration of the street lighting system to meet IEC standards,
saving of energy and resulting in a reduction in monthly electricity costs, plus after-sales services (maintenance
etc). As a result of the investment, the city achieved a reduction in its electricity bill from around IDR 2bn/month
to around IDR 0.6bn/month (75% saving), without reducing energy output.
However, the contractual arrangement was not able to be replicated due to the regulatory barrier identified above.
The regulations are designed to prevent corruption at the local government level. Under the arrangement
between Pasuruan and Fokus, the city made a down-payment covering part of the total cost of the project, and
then paid off the remainder through the generated monthly savings on the city’s PLN bill, plus interest. This
arrangement was investigated by BPK (the Supreme Audit Agency), mainly because of the interest paid by the
city to Fokus on the monthly instalments. The current regulations allow local governments to cooperate with PIP
(under the Ministry of Finance) and pay interest on their loans to PIP, but there is no clear regulatory provision
allowing entry into a loan-type agreement with third parties.
In addition, National law No.32 of 2004, which includes the protocol to be followed by local governments
regarding the receipt and use of different funding sources, prevents the use of tax receipts from local
governments to be directly paid to the private sector. Rather, tax receipts are to be kept within the city budget.
This creates significant uncertainty for both the ESCO and the PJU about whether the services can effectively
be paid for.
61
ESCO experiences in India – an example of making the ESCO model work
Over the last 4-5 years the ESCO model has gained momentum in India. This has been as a result of the rising
energy costs on the one hand, and initiatives by the national government to promote large scale implementation
of energy efficiency and energy conservation measures in existing facilities using the ESCO model on the other.
A national survey of 171 cities in 23 states showed that street lighting accounts for an average of 6.19% of
revenue expenditure of Urban Local Bodies (ULBs), yet only 0.88% of the total budget is allocated towards
energy efficiency activities by ULBs. There is an estimated saving potential of 60% of electricity consumption in
street lighting on average, nationally.
The national government decided to stimulate the ESCO industry as a way of unlocking this untapped potential.
To address barriers such as access to finance, absence of an industry association, lack of confidence of
prospective clients in the capacity of ESCOs, BEE (the Indian national energy efficiency agency) has now
enabled over 120 ESCOs through an accreditation process. This accreditation exercise has helped provide the
technical and financial due diligence necessary to create a sense of credibility amongst the prospective clients
who are likely to secure the services of an ESCO, as well amongst the financial institutions who are likely to
provide the debt and working capital to the ESCOs. Below is an example of an ESCO financing arrangement for
street lighting replacement in the Indian city of Rajahmundry.
Name of the city: Rajahmundry State: Andhra Pradesh Total number of street lights 10948 Total Investment: INR 7,000 Million Savings Achieved: 68.57% ESCO contract Period: 7 Years
Existing Load Numbers Watts Load (kW) Proposed Numbers Watts
Load (kW)
250W HPSV 832 285 237.12 70W LED 832 70 58.24
250W MH 93 285 26.505 70W 93 70 6.51
150W HPSV 1973 175 345.275 70W LED 973 70 68.11
36W LED 1000 36 36
70W HPSV 295 85 25.075 36W LED 295 36 10.62
40W FTL 7355 50 367.75 18W LED 7355 18 132.39
400W MH 488 450 219.6 180W LED 400 180 72
Total 1221.325 383.87
62
4.5.4 Assessment of financing options
Below, the financing options which were identified in the previous section have been evaluated using a
qualitative approach. The options are scored against the following criteria in the table below:
Potential volume of funds – options that can generate/source significant volume of funding are
generally scored more highly.
Timeframe for implementation – options that can be utilised more quickly are generally scored more
highly.
Equity issues – options which avoid perverse outcomes/unbalanced impacts on certain segment of
society are generally scored more highly.
Acceptability for policy makers – options which are likely to be politically acceptable (at both a federal
and local level) are generally scored more highly.
Transaction costs – options which avoid high transaction costs are generally scored more highly.
The options are scored against each of the criteria, with a green blob indicating a high score, orange
blob indicating a medium score, and red blob indicating a low score. An overall assessment is also
provided, in terms of how the option could form part of a NAMA financing package, which is to be
described in detail in the following section. Those options which are seen clearly as forming part of the
financing package, particularly in the demonstration phase, are given a yellow “smiley face”. For the
options which have a good potential to form part of the financing package, but where there are some
uncertainties which need to be overcome, or where it is necessary to make a case-by-case assessment,
these have been assigned with a yellow “pondering face”. Those options which are clearly not going to
play a role in the foreseeable future are given a red “frowning face”.
63
Table 22: Qualitative assessment of financing options
Assessment
criteria
Potential volume of
funds generated
Timeframe for
implementation
Equity issues Acceptability for
policy makers
Transaction
costs
Overall
assessment /
role in package
Revenue recycling
through metering
Savings of 40-60% on a
city’s PLN bill are
possible. E.g. in a medium
sized city with a bill of
30bn IDR p.a. this would
free up 12-18bn IDR (1-
1.6m USD). Scale-able
across the country.
Will take considerable
time. Payback over
several years.
Equity would
improve since
metering reduces
overcharging by
PLN
Policy makers should
be supportive at both
federal and local level.
PLN may resist.
Up-front cost of
meter installation is
high. Otherwise low
transaction costs.
Metering will play
an important role,
but need other
finance sources to
kick-start the SSLI
NAMA
Donor or National
Grant
(through ICCTF)
Grants of 5-15mEUR (7-
20m USD) are possible
through the NAMA facility.
No restrictions on the size
of grants that can be
disbursed through ICCTF.
If successful in the first
round of NAMA facility
grant applications, this
could generate a funding
stream by mid-2014.
None identified In line with GoI policy
objectives; ICCTF is an
established institution
Application
procedures for
ICCTF require TSU
support
Key source of
funds for kick-
starting the SSLI
NAMA in Phase 1
and 2
Carbon markets
(CDM, NMM, BOCM)
Limited potential.
Emissions reductions of
100-400kt CO2-e by 2020
@ 1 USD/CER =
100-400,000USD in total.
CDM is available now,
but market is
oversupplied to 2020.
NMM and BOCM are
uncertain at present.
None identified. Uncertain. CDM is
established, but NMM
is highly sensitive in
terms of international
climate negotiations.
Costs (PDD
development,
validation,
verification etc) can
be prohibitive.
Unlikely to play a
role in the intended
timeframe for the
SSLI NAMA
64
Assessment
criteria
Potential volume of
funds generated
Timeframe for
implementation
Equity issues Acceptability for
policy makers
Transaction
costs
Overall
assessment /
role in package
PIP loans
Loans of up to EUR11-
15m (15-20m USD) are
available in 2014-15;
potentially at a rate of 5%
under mandatory loans
program. Could help
leverage additional funds.
Established procedures
in place; loans could be
made available in 2014.
None, provided
that repayment
terms are not too
onerous on local
governments.
No issues at national
government level.
Some work needed at
local government level
to convince cities that
accessing PIP loans is
a good option.
Supported required
from TSU.
Application
procedure for PIP
loans needs to be
streamlined to avoid
delays/high
transaction costs.
Support required
from TSU.
Key source of
funds for
expanding the SSL
NAMA in Phase 2
and 3.
Street lighting tax
increase
Depends on city
circumstances. In some
cities, 10% limit has
already been reached.
Nationally, average is
around 7%.
Local governments must
pass legislation to
increase tax level.
Revenue receipts will
flow over time, rather
than up-front.
Consumers bear
the financial
burden unless the
cost savings are
shared with them.
Tax increase is likely to
face opposition from
citizens. A mandatory
national approach is
not likely to be popular
at local level.
No additional costs
aside from legislative
amendment. PLN
collects tax receipts
and transfers to local
government
Case by case
assessment. Not
likely to play a
major role overall,
but could suit some
cities.
ESCO financing
Potential is very high (up
to 75% savings), but
contracting needs to be
allowed by regulatory
framework.
Several ESCOs are
ready to start
implementing now/early
2014.
None, provided
benefits are
shared; some risk
of private sector
capturing benefits.
High level of interest,
but regulatory
uncertainty is the key
barrier to acceptability
at the local govt level.
Low if regulatory
framework is
clarified to allow
contracting and with
support from TSU.
High potential as a
key plank of the
finance package if
regulatory issue is
addressed.
65
4.5.5 Case studies demonstrating the use of different financing pathways
As outlined in chapter 4.5.1 the implementation plan foresees two pilot street lighting programmes for
the demonstration phase (four in the ambitious scenario). This section outlines the financing of the smart
street lighting roll out for these two cities in detail. To showcase two cities with quite different situations,
Yogyakarta is selected as a more modern, economically developed medium-sized city and Probolinggo
is selected as a less modern smaller city more based around the rural sector (agriculture etc). We will
outline a suitable mix of financing options and show key investment parameters and results that
demonstrate the profitability but also the risks of LED replacements. For both case studies with related
baseline and project scenario, limitations of data availability have to be considered. For example the
cities do not have a robust and consistent database listing a precise number of street lights. Such
constraints are also evident for the exact installation costs thus we have included a contingency rate of
30% for the installation costs of an average 140W LED. This covers, if required, the replacement of the
housing and new cabling related the LED.
Case study 1: Yogyakarta
Yogyakarta is a middle-size city located at the Southern coastline of the Indonesian island Java. It has
approximately 430,000 inhabitants and is known as economic hub of the region with an annual Gross
Domestic Product generation of about 675 million USD (bps, 2013). Being a centre of the historic
Javanese culture it is also an important touristic destination. Thus the electricity consumption of
assumed 860 kWh per inhabitant and year is significant compared to other regions or cities. For example
it is about one third higher than in Probolinggo, the other case study described in Figure 10 below.
Figure 10: Map of Java with Yogyakarta highlighted 25
Regarding the street lighting situation, Yogyakarta has reached a comparable advanced stage. The
estimated 19,000 street lamps, mostly medium efficiency HPS lamps, have been equipped with meters
25 http://www.happychap.eu/travel_info/indonesia_2008/java/railway_map_bestanden/image002.jpg
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already. This leads to comparably low electricity expenses as the remaining illegal connection are not
subsidized by Yogyakarta through the street lighting bill. Due to the high electricity consumption per
capita the revenues of the street lighting tax are also comparably high. They exceed the electricity bill
by about three times which allows almost sufficient resources for maintenance and replacement of
existing lamps. Only few general budget allocations are required for balancing the total street lighting
expenses. The municipality has gathered experience with energy efficient LEDs in a pilot programme
involving seven 140W LED units used to replace 250W HPS lamps. Based on the positive experience,
the PJU would like to invest in the replacement of further HPS lamps. The main challenge is the limited
funding available from the municipal budget for a full-scale LED replacement programme, despite the
positive balance of the street lighting tax. The PJU is interested in national government financial
incentives (grants, soft loans) if made available.
Table 23: Socio-economic and street lighting specific parameters of Yogyakarta (annually, 2008
data)
Parameter Baseline value
GDP 675,400,000 USD
Inhabitants 433,000
Street lighting tax revenues 2,200,000 USD
PJU electricity bill 720,000
Street lighting lamps ~ 19,000 (HPS dominant type)
Metering coverage ~ 100%
Source: GIZ PAKLIM (2012), 2nd mission report (Perspectives, 2013); bps (2013)
Baseline scenario: Our financial assessment shows that the budget for replacement of lamps at the
end of their lifetime (in average 5.4 years for HPS), electricity bills, metering and other O&M is almost
balanced by the tax revenues. However a shortage of about 10% in 2014, slightly increasing due to
rising electricity costs, constantly needs more allocation from the general budget of Yogyakarta.
The NPV derived over the assessment lifetime of 11.4 years (average lifetime of the LEDs) and
discounted with 8%/a leads to shortcomings of almost 3 million USD.
Efficient lighting scenario: We assume that the HPS lamps are replaced with LEDs as soon as they
have reached the end of their lifetime. As there is no detailed information about the current status of the
installed lamps available, we assume that about one fifth of the lamps have to be replaced every year.
Thus the total implementation time for the LEDs is completed in 2019. Electricity consumption is reduced
according to the lower wattage (140W instead of 250W); incremental costs for the replacement are
higher due to the LEDs. As financing options we assess an internal option without financial support first.
Hereby no NAMA grants and no PIP loans are considered, the municipality would attract funds for the
installation of efficient lamps from the financial market. Calculating with an internal discount rate of 8%
(represents the cost of capital) the NPV is about 325,000 USD over the lifetime. The IRR of the LED
implementation programme has a value of 9%. In this option the NAMA support would be provided
67
through technical advice through the TSU (e.g. assisting the PJU with performance specifications for
the LEDs prior to tendering).
The second option involves financial assistance from the Ministry of Finance, via PIP, to help overcome
the incremental cost of the LED replacement programme. The modelling simulates a PIP loan of 6.5
million USD provided over 5 years with an interest rate of 5% per annum and repayable from year three
onwards. We assume a payback amount of 750,000 to 1,000,000 USD per year until 2024. This
approach would increase the NPV to 3.5 million USD over the assessment period.
To illustrate the differences between baseline and efficient lighting scenario we show the annual net
cash flow over the lifetime of the LEDs. Whereas the baseline is constantly decreasing, the efficient
lighting starts to pay off from year 7 onwards when the electricity savings outnumber the additional
burden from higher replacement costs and PIP loan repayments.
Figure 11: Accumulated cash flows for the baseline and the efficient lighting scenario
(including PIP loans)
Case study 2: Probolinggo
Probolinggo is a small-medium-sized city located in the Southeast of Surabaya at the Northern coastline
of the Indonesian island Java (see red dot in the Figure 12 below). It has approximately 220,000
inhabitants and is a rather rural-oriented city with an annual Gross Domestic Product generation of about
190 million USD (bps, 2013). Its population mainly works in the agriculture and fishing sector. Thus the
electricity consumption per inhabitant is comparably low, we assume about 580 kWh per capita and
year.
68
Figure 12: Map of Java with Probolinggo highlighted 26
Regarding its street lighting system, Probolinggo faces a challenging situation. The PJU estimates that
around 15,000 street lamps are installed in the city, but only 4,000 connections have been validated by
PLN. The PJU estimates that 60-70% of all connections are illegal. The dominant lamp type installed is
low efficiency mercury lamps, and only around 10% of all lamps are covered with metering. This leads
to comparably high electricity expenses, since PLN charges the PJU for its consumption using the lump
sum approach, and assumes a high number of illegal connections, for which no tax income is received.
Because of the overall low electricity consumption in Probolinggo, the revenues of the street lighting tax
are also comparably low. As the total receipts are about 10% lower than the electricity bill, there are not
sufficient resources for maintenance and replacement of existing lamps. A significant amount of general
budget allocations are therefore required for balancing the total street lighting expenses. The
municipality has elaborated a “green city master plan” which includes replacement of Mercury lamps
with energy efficient LEDs in conjunction with metering but the financial challenges prevented its
implementation so far. The PJU has been approached by a number of suppliers/ESCOs but cannot
afford the up-front capital investment required for a full scale replacement programme. It is not expected
that this will change in a business as usual scenario.
26 http://www.happychap.eu/travel_info/indonesia_2008/java/railway_map_bestanden/image002.jpg
69
Table 24: Socio-economic and street lighting specific parameters of Probolinggo (annually,
2008 data)
Parameter Baseline value
GDP 187,500,000 USD
Inhabitants 220,000
Street lighting tax revenues 750,000 USD
PJU electricity bill 950,000
Street lighting lamps ~ 15,000 (Mercury dominant type)
Metering coverage ~ 10%
Source: GIZ PAKLIM (2012), 2nd mission report (Perspectives, 2013); bps (2013)
Baseline scenario: Our financial assessment shows that the budget for replacement of lamps at the
end of their lifetime (on average 5.4 years for HPS), electricity bills, metering and other O&M is cannot
be covered by the tax revenues. About 1.6 million USD from the city budget has to be allocated annually
for a proper operation of the system. This amount is slightly increasing due to rising electricity costs.
The NPV derived over the assessment lifetime of 11.4 years (average lifetime of the LEDs) and
discounted with 8%/a leads to shortcomings of almost 14 million USD. About 1.3 million USD of
additional city budget are required for balancing the expenses.
Efficient lighting scenario: We assume that the Mercury and HPS lamps are replaced with LEDs as
soon as they have reached the end of their lifetime. As there is no detailed information about the current
status of the installed lamps available, we assume that one fifth of the lamps have to be replaced every
year. Thus the total implementation time for the LEDs is completed in 2019. Electricity consumption is
reduced according to the lower wattage (140W instead of 250W), incremental costs for the replacement
are higher due to the LEDs. Additionally we assume that a metering system for all lamps is installed.
The metering costs would either be covered from the municipal government’s consolidated budget, or
require national government support. The NAMA TSU would support the local government in sourcing
financing to cover metering costs.Investment in metering is not assessed as part of the SSLI NAMA
financing package itself, but could form part of the unilateral NAMA component if supported by the
national government.
As financing options we assume a combination of three sources: A NAMA facility grant of 5 million USD
as well as a PIP loan of 6 million USD with 5% interest rate provided over the first 6 years are
representing the external support. We assume a payback amount of 750,000 USD per year until 2023.
The NPV of this scenario reflecting the PIP interest rate is about -5.7 million USD over the lifetime. The
street lighting system would need net allocation from the city budget up of about 500,000 to 700,000
USD annually until 2023. Afterwards the system will be able to finance itself without any further
contributions.
70
To illustrate the differences between baseline and efficient lighting scenario we show the net cash flow
over the lifetime of the LEDs. Whereas the baseline net cash flow is constantly decreasing, the efficient
lighting starts to pay off from the beginning compared with the baseline scenario, which aside from the
efficiency improvements is also due to the NAMA facility grant and PIP loans. From 2024 onwards
electricity savings outnumber the additional burden from higher replacement costs and PIP loan
repayments; the system starts to finance itself.
Figure 13: Development of the net cash flows for the baseline and the efficient lighting
scenario (including PIP loans)
4.5.6 Financing roadmap utilising a mix of sources
Below is a recommended roadmap for combining the selected financing options. This roadmap is
designed to enable a quick-start demonstration phase for the SSLI NAMA, followed by a scaling-up and
transformation phase. The ICCTF is seen as the most appropriate established mechanism to acquire
and administer international supported-NAMA funds, in order to:
Demonstrate NAMA implementation in selected pioneer cities
Strengthen city's capacities to install, maintain and monitor efficient street lighting
Overcome barriers through provision of support to municipalities and streamlining of processes, and
pave the way for expanded implementation via concessional finance administered through the PIP
and enabling use of the ESCO model in the scaling-up phase.
The concessional finance offered through PIP could then be combined with other means of domestic
financing (e.g. temporary increases in the street lighting tax or national government grants) to enable
scaled-up mitigation action.
In order to assess the financing requirements of the NAMA and its feasibility, the project team developed
a financial model that produces results for IRR, NPV and payback periods of the baseline and SSLI
71
NAMA project scenarios. The results of this analysis are provided below for each of the implementation
phases. Key assumptions applied in the modelling are presented in Section 4.5.1.
In the following, the finance roadmaps for the conservative and ambitious pathways are described,
distinguished by the three different phases.
Conservative pathway
Phase 1: Demonstration phase (January 2014 to June 2015)
A NAMA grant is sought to be paid into ICCTF, which would then administer the disbursement of funds
to two selected pilot cities from the following shortlist: Yogyakarta, Probolinggo, Makassar and
Pekalongan.
In total, a targeted grant of 14m EUR (20m USD) is sought, of which 8.5m EUR (11.5m USD) 27 is used
to provide funding for capital investment, including purchase of 15,000 suitable LEDs that substitute
10,000 HPS 150W lamps and 5,171 mercury vapour 250W lamps. For illustration, this would cover the
installed lamps in Pekalongan. Operation and maintenance is covered through the street lighting tax as
in the baseline scenario.
In addition to the capital investment, grant is to provide 5.5m EUR (7.5m USD) for technical assistance.
This supports the establishment of the TSU in MEMR, which will provide training for local governments,
and technical support for the establishment of energy efficiency performance and safety standards for
efficient lighting products at the national level, as well as supporting local governments which need to
conduct audits as a pre-condition for joining the SSL NAMA (to validate the number and type of lamps
installed).
In preparation for phase 2, the TA funding also enables TSU to support the local governments in
preparing proposals to access PIP loans and to help streamline PIP procedures. Together with PIP, the
TSU will further support uptake of the ESCO model by providing advice to local governments interested
in entering into contracts with ESCOs.
Phase 2: Scaling-up phase (July-2015 to end 2016)
In the scaling-up phase, two additional cities obtain access to concessional PIP loans to finance the roll-
out of SSL technologies. In conjunction with this, the TSU supports ESCO participation in at least one
of these cities by supporting the local government in entering into such an arrangement and by working
with PIP to facilitate the ESCO financing. The concept is that a PIP loan is used to pay the ESCO for
27 The value of 8.5m was chosen for conservativeness, to allow for a 500,000 EUR contingency in the case of higher than
anticipated capital costs.
72
the up-front component of the investment cost and the city then pays back the loan from its cost savings
over time. The PIP loan could either flow directly to the ESCO, or via the city.
Technical assistance provided by TSU includes training of additional local governments on maintenance
and MRV for the new cities joining the SSL NAMA. The TSU will also provide awareness raising of the
benefits of the SSL NAMA to help expand its coverage in the third phase.
In the second phase it will also become necessary to explore longer term financing options including,
for example, a new dedicated energy efficiency loans scheme administered by MoF or DAK grants. In
conjunction with financial support mechanisms, national electricity pricing reform options such as
reduction of electricity subsidies should be explored. The TSU can support the policy agenda by
providing advice on the options to be pursued.
Phase 3: Transformation phase (Jan 2017 to end 2019)
In phase 3, an additional 5 cities implement efficient street lighting under the SSLI NAMA.
Implementation of the SSLI NAMA is made possible through the combination of increasing experience
with PIP loans, the increasing contracting of ESCOs and potentially other measures (e.g. electricity price
reform acting as an incentive for cities to invest in energy efficiency improvements).
In our modelling, local governments continue to use PIP loans until the 40 million USD are fully exploited.
As soon as PIP loans are exhausted, ESCOs fill the gap, financing investments for up to 30 million USD.
This highlights the fact that ESCOs need to be stimulated/supported in the first two phases, and that
cities will need to free up resources for investment in the up-front costs associated with ESCO financing
(since PIP soft loans will not be available). They can do this either by allocating additional funds from
municipal budgets, going to the financial markets for loans or seeking national government support if
available (e.g. DAK grant). The assumed rate of return for ESCOs is 10%. The remaining costs are
covered through loans from the financial market where interest rates are assumed at 12%.
Technical assistance provided by the TSU includes training of additional local governments on
maintenance and MRV for the additional cities joining the SSLI NAMA. Facilitation of ESCO participation
will also be required based on the experience in the earlier phases. In the third phase, there is also the
need for the development of a long term budgeting plan for SSLI NAMA TSU, which could adopt a
broader energy efficiency focus.
The overall investment roll-out for the conservative pathway is illustrated in Figure 14. We see a
comparatively balanced use of different financial sources for covering the incremental installation costs.
First the NAMA grant will support funding the SSL technology during demonstration phase (blue line).
From 2015 PIP loans finance the additional roll-out during phase II (red line). After roughly 40 million
USD of PIP loans are exploited end of 2016, the ESCO model is used for further installations (orange
line). A total of 30 million USD is expected to be financed by ESCOs. Finally, the local governments
73
then rely on the financial market for financing the final share of the required 80 million USD investment
in 2018 and 2019 (purple line).
Figure 14: Investment roll-out under the conservative pathway
The financial benefits of the conservative scenario are illustrated in Figure 15. The blue line shows the
net cash flow of installation costs, operating costs and electricity savings compared to the baseline. The
discount rate is 8% annually (approximate average of PIP loans, ESCOs demands and financial market
loan interest rates). The cash flow stays negative as long as the installation of SSL technology is on-
going; from 2018 onwards we have significantly positive cash flows dominated by the electricity savings.
From 2019 onwards there are no additional installations of lamps assumed (the curve is still decreasing
due to the annual discounting of the cash flow). Considering a NAMA grant of about 12 million USD at
the beginning of the project, the overall NPV of the investment until 2024 is 3 million USD.
Figure 15: Discounted net cash flow under the conservative pathway
74
Ambitious pathway
Phase 1: Demonstration phase (January 2014 to June 2015)
A NAMA Facility grant is sought to be paid into ICCTF, which would then administer the disbursement
of funds to the four selected pilot cities: Yogyakarta, Probolinggo, Makassar and Pekalongan.
In total, a targeted grant of 14m EUR (20m USD) is sought, of which 8.5m EUR (11.5m USD) 28 is used
to provide funding for capital investment, including covering part of the costs of investment in 14,500
suitable LEDs that substitute 14,500 HPS 150W lamps and 20,100 LEDs that replace the same number
of mercury vapour 250W lamps. The lamp replacement costs not covered by a NAMA grant will be
enabled through PIP loans.
The TSU will facilitate take up of the ESCO model in the ambitious scenario, where at least one of the
cities in the demonstration phase finances a street lighting replacement programme by contracting with
an ESCO. A PIP loan is used to facilitate this, by covering the up-front payment component.
In addition to capital investment, the NAMA grant is to provide 5.5m EUR for technical assistance. This
supports the establishment of the TSU in MEMR, which will provide training for local governments, and
technical support for the establishment of energy efficiency performance and safety standards for
efficient lighting products at the national level.
Phase 2: Scaling-up phase (July-2015 to end 2016)
An additional eight cities implement efficient street lighting programmes under the SSLI NAMA. In our
modelling, local governments use PIP loans until the 40 million USD are fully exploited. As soon as PIP
loans are used up, ESCOs are contracted for investments totalling up to 30 million USD. This highlights
that in the ambitious scenario there is a need for enabling the ESCO model to work even sooner – by
the second phase it will play a major role in financing the NAMA. The assumed hurdle rate for ESCO
financing is 10%. The remaining costs are covered through loans from the financial market. Interest
rates are assumed at 12%.
Technical assistance provided by TSU includes training of additional local governments on maintenance
and MRV for the additional cities joining the SSLI NAMA, plus facilitation of ESCO participation. TSU
also explores longer term financing options including MoF energy efficiency loans.
28 The value of 8.5m was chosen for conservativeness, to allow for a 500,000 EUR contingency in the case of higher than
anticipated capital costs.
75
Phase 3: Transformation phase (January 2017 to December 2019)
An additional 10 cities implement efficient street lighting under the SSL NAMA. In our modelling, it is
assumed that for covering the installation costs they use loans from the financial market. Interest rates
are assumed at 12%. Other financing options could make lower cost implementation possible, if for
example ESCOs were supported by a dedicated energy efficiency finance mechanism offered by the
national government (MoF) or if DAK grants were made available for street lighting replacement. For
the purposes of the financial modelling, such hypothetical sources of finance are not included.
As in the conservative scenario, the TSU supports local governments involved in the SSL NAMA on the
technical side and with help accessing finance. The TSU is eventually adopts a broader energy
efficiency focus as the NAMA comes to an end.
The overall investment roll-out is illustrated in Figure 16. Substantial new sources of finance (e.g. ESCO
financing, commercial loans from the financial market or other forms of public financing) will be required
to provide loans for the incremental installation costs from 2015 onwards. First the NAMA grant will be
sufficient for funding the SSL technology of the first two cities (blue line). However, already during the
demonstration phase, PIP loans have to finance the additional roll-out (red line). After the roughly 40
million USD of PIP loans are exploited in the first half of 2015, the ESCO model is used for further
installations. In this hypothetical scenario, it is assumed that a significant share of about 310 million USD
of financing has to be covered through regular loans at an interest rate of about 12%. In practice, any
combination of new sources of finance should be drawn upon to enable the wider expansion of the SSLI
NAMA to achieve transformational scale. Such an inclusion of additional new sources is reflected in a
second investment scenario below.
Figure 16: Investment roll-out ambitious pathway
The financial benefits of the ambitious scenario are illustrated in Figure 17. The green line shows the
net cash flow of installation costs, operating costs and electricity savings compared to the baseline. The
discount rate is 8% annually (approximate average of PIP loans, ESCO demands and financial market
76
loan interest rates). This scenario considers a 11.5 million USDNAMA grant. The cash flow stays
negative as long as the installation of SSL technology is on-going. From 2018 onwards significantly
positive cash flows dominated by the electricity savings are generated. From 2019 onwards there are
no additional installations of lamps assumed (the curve is still decreasing due to the annual discounting
of the cash flow). The overall NPV of about minus 7 million USD is still negative.
Figure 17: Discounted net cash flow under the ambitious pathway
This highlights the need for additional sources of finance in order to make the SSLI NAMA commercially
attractive for the large number of Indonesian cities being targeted under the ambitious pathway. If
another international donor and/or the Indonesian Government were to provide a second grant of 11.5
million USD for the NAMA, equivalent to the intial NAMA grant, the net benefit becomes positive earlier
and generates an overall positive NPV of about 15 million USD over time.
Figure 18: Discounted net cash flow under the ambitious pathway with additional 11.5 million
USD grant
Figure 19 below compares the overall investment needs estimated for the two pathways.
77
Figure 19 Comparison of investment needs in the two pathways
Table 25 summarises the key characteristics of the two financing pathways described above. It
highlights the need for additional sources of finance to ensure a positive NPV in the ambitious scenario.
Table 25: Summary of financing pathway modelling
Conservative pathway Ambitious pathway
Phase I:
Demonstration phase
Jan 2014 - Jun 2015
2 cities
NAMA grant 14m EUR
PIP loans (5%)
4 cities
NAMA grant 14m EUR
PIP loans (5%) ESCO financing
of one city
Phase II:
Scaling-up phase
Jul 2015 – Dec 2016
2 additional cities join
PIP loans (5%)
ESCO financing of one city
8 additional cities join
Additional grant 11.5m USD
40m USD PIP loans (5%)
30m USD ESCO financing (10%)
Phase III:
Transformation phase
Jan 2017 – Dec 2019
5 additional cities join
40m PIP loans (5%)
30m ESCO financing (10%)
80m USD regular loans (12%)
10 additional cities join
310m USD regular loans (12%)
NPV to 2024
(8% discount rate)
3m USD -7m USD with commercial loans
as per Phase III
+15m USD with an additional
grant of 11.5m USD)
4.5.7 Challenges to be overcome in the financing roadmap
In order to unlock the potential for the PIP loans as a way of scaling-up finance for the SSLI NAMA, a
number of existing hurdles will need to be overcome. At the moment the application for PIP loans
involves a lengthy and bureaucratic process, and seems quite discouraging in general for municipal
78
governments. Municipalities are currently unwilling to take loans, mainly because the guarantees
required by PIP are substantial. Collateral needs to be provided as a guarantee by the local government
and if they default, the value of the loan will be forcibly recouped by the MoF from the municipal budget.
Preconditions include the establishment of a local law that shall guarantee that public funds are made
available to match with the loan repayment period.
One option is to back the required guarantees through the ICCTF or through another international
funding vehicle (there is some history of ADB having done this). MoF would also have to determine that
energy efficient street lighting is covered under the “Mandatory” loans component in order to be able to
offer loans at 5% interest rates. Initial discussions with PIP have indicated a high level of willingness to
engage with municipal governments on financing for street lighting efficiency improvements.
Unlocking the potential of using the ESCO model will also require certain barriers to be overcome - in
particular, the lack of clarity in the regulations pertaining to use of local government tax revenues, and
payment of interest to third parties which is required for such contracting. This requires amendment of
the national regulations to clarify that ESCO contracting arrangements are not corrupt practices under
the appropriate circumstances. The TSU will also need to spend considerable time and resources on:
Raising awareness of the potential for energy efficiency services contracting as a way of
financing street lighting replacement;
Working with local governments to develop regulations to enable such contracting; and
Working with PIP to enable loans to be utilised by ESCOs (could also be channelled through
local governments to pay ESCOs for their services).
For certain municipalities, it may be possible to use the funding raised from the street lighting taxes to
finance replacement of inefficient lamps, but this seems only likely to generate a surplus once a high
level of metering has been installed. This will require a substantial up-front investment. Each individual
city will have to make its own considerations in this respect, and it is recommended that the national
government prioritise metering and help encourage cities to make this investment.
4.5.8 Recommendations
1. Utilise international NAMA support in combination with domestic finance sources to kick-start the
SSL NAMA Implementation. International NAMA support funding provided by a grant could provide
10-12m USD to be administered via the ICCTF. This should be used for SSL lighting replacement
investment in 2-4 targeted cities in the demonstration phase from early 2014 – mid 2015.
2. An additional 6-8m USD funding should be sought for technical assistance, specifically for the set-
up and operation of the TSU to support local governments in accessing domestic finance via the
ICCTF, loans from PIP and potentially other sources.
3. As a priority, the national government should enable local government to enter into contractual
arrangements with ESCOs by reforming the regulatory framework.
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4. TSU should work with PIP to smooth the process for entering into soft loan arrangements with
municipal and provincial governments. Consider using PIP loans to help cities enter into ESCO
arrangements.
5. In the scaling-up phase, from mid 2015-end 2016, aim for a further 2-8 cities joining the SSLI NAMA,
supported primarily via PIP loans and ESCO financing. In the transformation phase, from early 2017
to end 2019, aim for further 5-10 cities joining the SSLI NAMA, supported by PIP loans, ESCO
financing to the extent possible. Once exhausted, either commercial loans or new sources of finance
will be required.
6. Under the ambitious scenario without new sources of donor finance or national government financial
incentives (e.g. DAK grants or a dedicated loans facility for energy efficiency), the NPV will be
negative in 2024. In order to present an economically attractive option for the municipalities,
additional sources of NAMA finance would be required. For example, a second grant of 11.5m USD
during the transformation phase would generate a positive NPV. International donors but also
national, public institutions should be approached for financing.
It should be noted that the results of the analysis of the costs and benefits for the two SSLI roll-out
pathways presented here are based on many generalised assumptions, and are for illustrative purposes
only. In practice, each individual city that is interested in participating in the SSLI NAMA will need to
develop its own financing plan in cooperation with the TSU and MoF, and the individual circumstances
can be expected to vary significantly from city to city.
4.6. Estimated emissions reductions and abatement costs
4.6.1 Estimating emissions reductions against the baseline
A proposed baseline determination approach was outlined in Section 4.3. Once the baseline for each of
the cities participating in the SSLI NAMA has been established, it will be possible to estimate the
emissions reductions from the SSLI NAMA based on the calculated energy savings. As a rough
indication of the overall potential energy savings that could be achieved, we recall that street lighting
accounted for 3,068 GWh of electricity sales by PLN in 2011 according to the national statistics. If we
were to assume savings somewhere between the modelled results for the two case studies, where a
40% reduction was achieved, and the actual results in the Pasuruan case, where a 75% reduction was
achieved, this suggests a 50-60% reduction could be achieved nationally. That is, roughly 1,500-1,850
GWh of electricity saved per annum compared with business as usual. The key uncertainty is that
without metering, it is impossible to know the actual level of consumption, since the PLN sales are likely
to overestimate consumption significantly, as was discussed earlier.
For conservativeness, it is important to isolate the reductions that are due to the lighting replacement
itself versus other factors that could also contribute to energy savings, such as replacement of cabling
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for example. Following a street lighting replacement (14 LEDs substituted 14 HPS lamps) and metering
installation trial in Malang, Osram found significant energy savings were possible compared against the
baseline scenario. For the lamp replacement alone, Osram calculated savings of around 44% for an
equivalent lighting output based on the rated wattage of the installed LEDs (288W vs 159W). However,
based on the metered data Osram found that the total power after 1 month for LED was 805W compared
with 2386W resulting in an energy saving of around 66%. It is likely that the replacement of cabling and
grounding equipment also contributed significantly to the reduced power consumption of the LED
lamps29. Another likely factor contributing to savings is the deterioration of electronic ballasts of existing
lamps. In one study, Osram conducted laboratory measurement of a sample of lamps and found that
the ballasts used 60 W instead of the rated 36 W (i.e. +67% more)30. Thus, a conservative expectation
is that savings of around 40% are likely on a pure lamp-replacement basis, but under optimal conditions,
it is possible that LEDs can reduce energy by as much as 60% against the baseline scenario of HPS
lighting (GIZ PAKLIM, 2012).
4.6.2 Approach based on CDM methodology AMS-II.L
The approach for calculating the gross electricity savings in AMS-II.L is to multiply the total average
power of the installed (programme) luminaires multiplied by the annual hours of operation, compared
with the average power rating of the baseline luminaires, multiplied by the baseline annual hours of
operation (assumed number of daily operating hours multiplied by 365 or the number of days per year
that the lamps are expected to be operated). The approach then produces the net electricity savings
(NES) by correcting the gross electricity savings for any leakage and transmission & distribution losses.
The key data required for the emissions reduction estimation is outlined in the Table 26 below.
29 This was suggested by Osram during an interview in July 2013.
30 Interview with PT Osram in July 2013.
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Table 26: Key data required for emission reduction calculations
Data Potential source
Estimated number of conventional lamps and EE lamps
Data provided by cities on the number of lamps replaced under the SSLI NAMA
Nameplate/rated power wattage for conventional and EE lamps (use average, if not know for each lamp type)
Manufacturer information and/or measuring of replaced lamps
Assumption operating hours (default value for daily hours of operation of luminaires)
Operating hours could be based on of the change in streetlights turning ON time and OFF time depending on the sunrise and sunset times through the year.
Emission factor of the electricity grid (GEF)
Use values published/updated by MEMR.
Transmission & distribution loss
Data from PLN or MEMR. The average annual technical grid losses shall be determined using recent, accurate and reliable data available for the host country. Or could use 10% default value, if no specific figure is available (as per CDM methodology AMS-II.L)
Emission reductions hence depend on the energy efficiency savings between the replaced and installed
light bulb and applying the approach in AMS-II.L are calculated as follows:
yyy PEBEER (1)
Where:
= Emission reductions in year y (tCO2-e/yr)
= Baseline emissions in year y (tCO2-e/yr)
= Programme emissions in year y (tCO2-e/yr)
Thus, baseline emissions are determined by: the number of conventional lamps, the nameplate/rated
power wattage (average, if not know for each lamp type), the assumed operating hours (default value
for daily hours of operation of luminaires), TDL losses (10% default for instance, if no specific figure is
available) and the GEF for the respective grid in Indonesia. The programme emissions under the SSLI
NAMA are determined by the same parameters, but applying the number of efficient lamps and their
nameplate/rated power wattage or weighted averages if multiple lamp types are installed. Both, BEy
and PEy are used to calculate the emissions reductions (ER) as described below.
Emission emissions from net electricity saved are calculated as follows.
(2)
Where:
(1)
yER
yBE
yPE
ELyi
n
i
y EFTDLESER
)1(1,
1
yiyPiPiBLiBLiBLiyi OPQOPQES ,,,,,,,, ****
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Where:
= Emission Reductions in year y (tCO2-e)
= Estimated annual electricity savings for equipment of type i, for the relevant
type of project equipment in year y (kWh)
= Grid emission factor for electricity generation (tCO2/kWh)
= Average technical transmission and distribution losses for providing electricity
Pi,BL = Rated power of the baseline luminaires of the group of i lighting devices (kW), or time-integrated average power if equipment operates at various power settings, constant value independent from y
Pi,P,y = Rated power of the project (NAMA) luminaires of the group of i lighting devices (kW), or time-integrated average power if equipment operates at various power settings, normally constant value independent from y unless operating schedule or parameters changes during crediting period
( and )
Quantity of baseline (BL) or project (P) luminaires of type i distributed and installed under the project activity (units). Once all of the project luminaires are distributed or installed, Q i,P is normally a constant value independent from y unless size of operating luminaire inventory decreases during crediting period, in which case only operating project luminaires shall be credited.
Y = Crediting year counter
I = Counter for luminaire type
N = Number of luminaires
For the estimation of the potential total emissions reductions of the SSLI NAMA the above approach
has been applied for the actual PJU data available for the cities targeted in the Demonstration Phase
and the Scaling-up Phase as described in Section 4.5. For the transformation phase, the approach taken
was to extrapolate the emissions reductions using a hypothetical medium sized “model city” baseline as
outlined in Section 4.3.
Table 27 below summarises the baseline data used for the emissions reduction estimation for the
targeted cities where real data was available.
Table 27: Summary of city level data used for emissions reduction estimation
Parameter Semarang Probolinggo* Malang Mojokerto Yogjakarta* Surakarta Pekalongan
(pieces) (pieces) (pieces) (pieces) (pieces) (pieces) (pieces)
Mercury
125W
0 0 438 0 0 0 0
Mercury
250
2,193 6,000 2,740 757 4,000 12,318 5,140
HPS 70W 25,681 0 0 155 0 200 150
HPS 150W 22,927 9,000 400 235 8,000 0 400
yER
yjES ,
ELEF
TDL
iQ
BLiQ , PiQ ,
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HPS 250W 10,561 0 1,643 665 7,000 1,750 1,000
TL 35W 39 0 0 39 0 442 0
Duluxstar
45W
0 0 0 0 0 419 0
HWL 160W 0 0 0 0 0 0 0
Bulb 200W 0 0 0 0 0 171 0
Total lamp
numbers
61,401 15,000 5,221 1,851 19,000 15,300 6,690
Weighted
average
W/unit
137.2 190 231.9 217.7 136.3 235.3 240.0
Inhabitants 2,067,000 217,062 820,243 120,132 433,539 506,397 281,434
Road
length
727 195 192 112 244 275 128
Installed
meters
2,738 ~10% ~50% ~100%
Street
lighting tax
level (in %)
8 8 7 10 8 9 9
Tax
revenues
(USD/a)
9,450,000 750,000 2,200,000 300,000 2,200,000 2,880,000 1,000,000
PJU Bill
(USD/a)
3,595,406 950,000 1,400,000 ?? 720,000 2,400,000 1,030,000
Source: Data collected from city PJUs
For the hypothetical model city, an adjusted (truncated) average of the data for the real cities was used
to derive a city with the following characteristics:
population of around 890,000 and 502 km of roads
25,000 installed street lamps
average wattage of 202W/lamp
4.6.3 Results of emissions reduction estimation
The Figure below summarises the annual emissions reduction estimation results for the two replacement
pathways. It shows annual emissions reductions reaching around 60k tCO2-e by 2020 in the
conservative pathway, and around 200k tCO2-e in the ambitious pathway.
It should be noted that the baseline (red line) is simply the aggregated level of BAU emissions associated
with power consumption from currently installed street lighting in the cities covered by the ambitious
pathway – i.e. the total emissions that would occur if the SSLI NAMA were not implemented in any of
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these cities. In practice, each city participating in the SSLI NAMA will have its own baseline, as per the
approach outlined in Section 4.3.
Figure 20: CO2 reductions under the conservative and ambitious pathway
The estimated cumulative emissions reductions for the SSL NAMA over the two emissions reduction
pathways are summarised in the Table 28 below.
Table 28: Summary of results from emissions reduction estimation for both pathways
Pathway Phase Cumulative
lamps
replaced
(units)
Cumulative
energy
Savings
(MWh/a)
Cumulative
ER to 2020
Associated
cumulative
investment cost
(USD)
Conservative I 34,000
16,381
69,899 27,553,600
II 65,690
31,649
119,719 53,235,176
III 191,232
92,135
210,811 154,974,183
Ambitious I 65,690
31,649
135,048 53,235,176
II 266,557
128,427
450,833 216,017,587
III 517,640
249,399
640,608 419,495,601
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Overall, this suggests that by 2020 the SSL NAMA could achieve emissions reductions of around 210k
tCO2-e in the conservative pathway, and up to around 640k tCO2-e in the ambitious pathway. When the
total energy savings over the lifetime of all lamps installed is accounted for, the emissions reductions
would of course increase as the estimation is extended beyond 2020. By 2024, it is estimated that the
SSLI NAMA could reduce emissions by as much as 1.5 Mt tCO2-e in the ambitious pathway.
4.6.4 Estimated cost of abatement
Initial estimates of the abatement costs associated with the above emissions reductions have been
derived applying an NPV approach comparing the total capital and O&M costs against the levelized
electricity cost savings over time to 2024, discounted at 8% (all other assumptions are the same as
described above, including CAPEX, electricity price assumptions, NAMA facility grant etc). In summary,
the estimated cost of abatement for both pathways is negative, reflecting the positive payback of the
SSLI NAMA over time resulting from electricity cost savings:
For the conservative pathway the estimated cost of abatement is around -4 EUR/t CO2-e
For the ambitious pathway, the estimated cost of abatement is in the order of -8 EUR/t CO2
Increasing the discount rate has a material impact on the results, but the estimated abatement costs are
still negative at, for example, 10%, which would increase the cost of abatement to -1 EUR/t and -5 EUR/t
respectively for the two pathways.
4.7. Installation and maintenance
This chapter deals with the identification of existing installation and maintenance processes in Indonesia,
the stakeholders involved in the process, assessing the capacity needs of the sector based on an
identification of major gaps, strategizing a capacity building process for installation and maintenance of
LED street lighting including the identification of additional support units to be involved in the process.
4.7.1 Background
City governments, Local General Works Agency, Local Environment Agency, Agency for Hygiene and
Landscape Gardening and Transportation Agency are the organizations responsible for the installation
and maintenance of street lighting at the local level. The PJU houses in one of these agencies and carry
out the necessary activities for installation and maintenance of street lights. Based on discussions with
these organizations, the administrative structure and capacities of these organizations to support energy
efficient street lighting implementation in Indonesia have been assessed and training needs is identified.
Based on the capacity needs assessment of various departments involved in the activity, a capacity
building strategy has been provided.
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4.7.2 Organizations involved in the installation and maintenance of Street lighting
4.7.2.1 City Government:
The city government has the authority to install and operate street lights at the local level. The installation
of street lights is financed from the city budget. After completion of installation, further operation and
maintenance responsibilities are delegated to related Dinas. Dinas are local government agencies
working in the field of environment, general works, hygiene, landscape gardening etc.
4.7.2.2 Municipal Public Lighting Agencies (PJU)
Within the local government, a specific unit, PJU is assigned to manage street lighting. This unit is
usually integrated into one of the following local government agencies:
Local General Works Agency (DPU – Dinas Pekerjaan Umum)
Local Environment Agency (BLH – Badan Lingkungan Hidup) and
Agency for Hygiene and Landscape Gardening (DKP – Dinas Kebersihan dan Pertamanan)
Transportation Agency
4.7.2.3 National Electricity Utility - PLN
PLN is not directly involved in installation and operation of street lighting; but periodically monitors legal
and illegal street light connections in urban areas. PLN is responsible for installing and reading electricity
metering for street lighting.
4.7.2.4 The manufacturers and suppliers of street lighting technologies
The manufacturers and suppliers of street lighting equipment are private entities which are also largely
responsible for their installation and maintenance. Cities usually select these companies through a
competitive bidding process so as to ensure quality services and selection of the best technology.
Fokus Indo Lighting is the leading supplier of street lighting equipment in Indonesia by market share.
Philips and Osram are other suppliers which are expanding operations in the country.
4.7.3 General guidelines for Installation of LED/Smart Street lighting
Guidance for lighting of public streets, roads, and highways is provided in the Indonesian Standard (SNI,
2008). Since these guidelines are not enforced by any regulatory authority, local governments tend to
be unaware of the standards, and many fail to comply. In order to properly design new lighting schemes,
it is important to consider the appropriateness and effectiveness of the various energy efficient street
lighting technologies and systems for different situations. Street lighting technology and design
decisions should be based on meeting local lighting requirements while achieving maximum energy
efficiency.
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Most importantly, the design of a street lighting system must be appropriate for the site and should
provide the level of illumination (lux) and uniformity of light as per the recommended standards.
Decisions about lighting systems should also take into account characteristics of lamp efficacy, good
colour rendering, and light distribution. Listed below are features to consider for designing and procuring
an energy efficient street lighting system:
Proper pole height and spacing
Proper luminaire aesthetics
High lamp efficacy and luminaire efficiency
Life of the luminaire and other components
Cost effectiveness
High lumen maintenance
Good colour rendering
Short lamp restrike
Proper light distribution
Proper cut-off
Minimizing light pollution and glare
Automatic shutoff
4.7.3.1 Types of street lighting poles:
Table 29 provides general standards for street lighting poles. Selection of an optimum quality pole
having appropriate diameters at different length segments of the pole is important in installation of new
street lighting system. Pole diameters for different height segments of a pole are provided below. Based
on requirements, users may select an appropriate design. A, B, C, D is defined as different height
segments of a pole starting from its bottom A and reaching to its peak D while H is the complete pole
height.
Table 29: Specifications for street lighting poles
Dimension of Street Lighting Poles
Segments Pole Diameter (mm) Pole Height Alternatives (meters)
I II III
A 150 3.5 5.5 5.5
B 125 2.1 2.1 3.1
C 100 2.1 2.1 3.1
D 75 3.3 3.3 3.3
H Total 11.0 13.0 15.0 Source: SNI 7391:2008
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4.7.3.2 Pole Height for street lighting:
One of the important aspects of design based street lighting systems31 is to determine the optimum pole
to pole distance, as per the width of the road and the mounting height of the pole. The optimum pole
distance should be chosen based on the light output of the sources, the light distribution of the
luminaires, and the geometry of installation. The mounting height should be greater for powerful lamps,
to avoid excessive glare. Table 30 and Table 31 show the pole to pole distance as per the varying pole
height and width of the roads.
Table 30: Distance between poles (in meters) based on typical lighting distribution and classification of
lights (Lantern A32)
Type of Lamps Height of Poles
(meters)
Width of the road (meters) Illuminance
4 5 6 7 8 9 10 11
35W SOX33 4 32 32 32 - - - - - 3.5 LUX
5 35 35 35 35 35 34 32 -
6 42 40 38 36 33 31 30 29
55W SOX 6 42 40 38 36 33 32 30 28 6.0 LUX
90 W SOX 8 60 60 58 55 52 50 48 46
90 W SOX 8 36 35 35 33 31 30 29 28 10.0 LUX
135 W SOX 10 46 45 45 44 43 41 40 39
135 W SOX 10 - - 25 24 23 22 21 20 20.0 LUX
180 W SOX 10 - - 37 36 35 33 32 31
180 W SOX 10 - - - - 22 21 20 20 30.0 LUX
Source: SNI 7391:2008
31 A design based street lighting system should permit users to travel at night with good visibility, in safety and comfort, while
reducing energy use and costs and enhancing the appearance of the neighbourhood.
32 Lantern A has a wider spreading of Lighting/spot light
33 SOX are low pressure sodium lamps
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Table 31: Distance between poles (in meters) based on typical lighting distribution and classification of lights (Lantern B34)
Type of Lamps Height of Poles
(meters)
Width of the road (meters) Illuminance
4 5 6 7 8 9 10 11
50 W SON35 or 80 W MBF/U36
4 31 30 29 28 26 - - - 3.5 LUX
5 33 32 32 31 30 29 28 27
70 W SON or 125 W MBF/U
6 48 47 46 44 43 41 39 37
70 W SON or 125 W MBF/U
6 34 33 32 31 30 28 26 24 6.0 LUX
100W SON 6 48 47 45 42 40 38 36 34
150W SON or 250W MBF/U
8 - - 48 47 45 43 41 39 10 LUX
100W SON 6 - - 28 26 23 - - -
250W SON or 400W MBF/U
10 - - - - 55 53 50 47
250W SON or 400W MBF/U
10 - - 36 35 33 32 30 28 20 LUX
400W SON 12 - - - - 39 38 37 36 30 LUX
Source: SNI 7391:2008
Spacing Spacing is the distance, measured along the center line of the road, between successive luminaires in
an installation. To preserve longitudinal uniformity, the space-height ratio should generally be greater
than 3.
Outreach Outreach is the horizontal distance between the center of the column and the center of the luminaire
and is usually determined for architectural aesthetic considerations
Overhang Overhang is the horizontal distance between the center of a luminaire mounted on a bracket and the
adjacent edge of a carriage way. In general, overhang should not exceed one-fourth of the mounting
height to avoid reduced visibility of curbs, obstacles, and footpaths.
Recommended Level of illumination: Table 15 in the standards chapter gives information on recommended level of illumination on different
categories of roads. The different types of roads have been classified in to categories based on the
34 Lantern B has a smaller spreading of Lighting/spot light and directly to the road
35 SON are high pressure sodium lamps
36 MBF/U are mercury vapor lamps
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Indonesian context, and the recommended level of illuminance, luminance and glare limitation are given
for each type of road.
4.7.3.3 Type of lamp technology:
Various types of street light lamps are available in the market and the user has to select the appropriate
lamps before installation. Table 32 provides an overview of the different types of lamps covered in the
national standard (SNI, 2008) and the expected results from those lamps in terms of efficiency, lifetime,
power rate, object colour etc (LEDs are not covered by the standard).
Table 32: Lamp Technologies
Type of Lamp Average
efficiency
(lumen/watt)
Average
lifetime
(hour)
Power rate
(watt)
Impact
to object
colour
Remark
Low pressure
Fluorescent
60 -70 8,000 –
10,000
18 – 20
36-40
Medium Collector and local road
Efficiency is quite high but
lifetime is short
Acceptable for limited
application
High
Pressure
Mercury
(MBF/U)
50 – 55 16,000 –
24,000
125;
250;400;700
Medium Collector, local road and
intersection
Efficiency is low, lifetime is long
and size of lamp is small
Low Pressure
Sodium
(SOX)
100 – 200 8,000 –
10,000
90;180 Very bad Collector, local, intersection,
overpass, tunnel, rest area
Efficiency is high, lifetime is
quite long, size of lamp is big so
difficult to control the light and
colour of lamps is yellow
This type is recommended since
the efficiency is high
High
Pressure
Sodium (HPS)
110 12,000 –
20,000
150;250;400 Bad Highway road, artery, collector,
big size intersection, and
interchange
Efficiency is high, lifetime is
long, size of lamp is small and
easly to control the light
This type is recommended
Source: SNI 7391:2008
4.7.4 General guidelines for maintenance of LED / Smart Street lighting
Energy consumption for LED street lighting can be reduced by incorporating good maintenance
practices such as:
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Replacing defective lamps, accessories, and wires
Early rectification of cable faults
Making sure that cables are joined properly
Regular maintenance of service cabinet/fuse box to avoid loose connections
Regular cleaning of the luminaire cover to keep it free of dust/dirt and increase light output
A substantial amount of energy savings can also be achieved by installing mechanical/electronic timers
and/or daylight sensors for turning street lights on and off.
Besides installation and maintenance, the city governments are also involved in the waste handling of
the scrap street lights. Generally, cities store the non-burning lights in the warehouse with no formal
waste management practices being followed. In some cities, it is understood that informal scrap-
collectors (scavengers) collect broken lamps and salvage the aluminium parts for resale.
4.7.5 Identification of gaps
Lack of awareness on installation and maintenance practices
Most cities do not have updated and correct information on installation and maintenance practices for
street lighting. In the absence of such information, cities rely on inputs from local suppliers to make
decisions. This lack of information impacts implementation of effective and efficient street lighting
solutions, causing inconvenience to citizens.
Noncompliance of installation and maintenance practices
Standards issued by the national government are not complied with. Discussions held with several cities
revealed mixed responses to compliance with installation and maintenance practices suggested by
Indonesian standards. Cities are also not equipped with necessary facilities to monitor compliance with
maintenance procedures, once lighting solutions are installed.
Lack of manufactures, suppliers and installers at the local level
Lack of good manufacturers, suppliers and installers at the local level who have a clear understanding
of the installation and maintenance guidelines is a major factor contributing to poor delivery of quality
street lighting services to citizens.
Lack of maintenance staff in cities
Cities do not have enough budget allocated to hire enough trained people as maintenance staff to
effectively maintain existing street lighting systems in cities.
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Waste disposal practices of discarded lamps
The cities also do not have access to scientific waste disposal facilities to disposal standards for end of
life luminaires. In the absence of such facilities, cities dump all non-functional street lights in warehouse
without any segregation.
4.7.6 Recommendations:
Adoption of installation and maintenance practices
Cities should adopt standard installation and maintenance practices which are indicated in this chapter.
Design based street lighting, ensuring compliance with all parameters specified in the standards, will
greatly improve the quality of street lighting in urban areas.
Awareness and capacity building activities at the local level for installation and maintenance
Awareness and capacity building programs at the local level will greatly help in improved delivery of
services to the people. Lack of awareness on design based street lighting results in adoption of
inappropriate technologies, which do not provide the necessary level of service to citizens. Awareness
and capacity building programmes for local governments should be undertaken to address these
concerns.
Preparation of Training Modules
Training modules should be developed in consultation with local stakeholders concerned with
installation and maintenance of street lighting technologies, while also considering local implementation
issues. The training modules should be developed for various categories of staff working at different
levels within the PJU and other concerned departments:
Senior Administrators and policy makers
Senior Engineers / Junior Engineers
Technicians involved in the installation and maintenance of street lighting
Suppliers of street lighting technologies
Delivering the training programs
Training programs should be delivered in a phased manner to monitor the outcome of the training
programs, to facilitate bridging of all identified gaps. Training programmes will be delivered to educate
senior officials, and other stakeholders on the benefits of energy efficiency street lighting and aspects
to be considered for installation and maintenance of smart street lighting. Training programs for
technicians aim to enhance their installation and maintenance skills.
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Table 33: Overview of training programmes
Target Group Focus Areas Brief Contents Duration / City
Senior officials, policy makers & stakeholders
Macro issues, importance of installation and maintenance issues
Global energy scenario, demand and supply, energy security.
Energy scenario of Indonesia, major threats, challenges.
Potential lies in energy efficient lighting system including that of LED streetlights.
Major gaps in installation and maintenance practices and how it can be resolved.
One Day
Senior Engineers / Junior Engineers
General considerations for design based street lighting and maintenance practices
Identification of needs and lighting requirements of road
Identification of best available technology and design to meet the lighting requirement
Procurement and tender evaluation
Operation and maintenance practices
Measurement and evaluation
One Day
Technicians involved in the installation and maintenance of street lighting
Practices to be adopted for installation and maintenance on ground
General practices to be adopted in installation and maintenance.
Replacement of defective lamps, accessories and wires
Early ratification of cable faults
Regular maintenance of service cabinet/fuse box to avoid loose connections
Regular cleaning of the luminaire cover to keep it free of dust / dirt and increase light output
Two Days
Suppliers of street lighting technologies
Installation material and supplies complying with applicable standards
All the installation and maintenance practices are applicable to the suppliers if they are involved in installation and maintenance.
Information on applicable standards so that they can comply with them.
One Day
4.7.6.1 Waste Management practices:
Safe disposal of lamps is also one of the concerns of local governments. The use of various types of
street lights including CFLs, metal halide, and mercury vapour, release lead, mercury and other
hazardous materials during their disposal phase. In contrast to conventional lamps, LEDs do not contain
mercury, lead or other toxic chemicals, and are completely recyclable. This translates into less localized
hazardous waste at the end of the product’s life cycle.
However, there is a school of thought which believes that LEDs also have toxic materials. A study
published in late 201037 in Environmental Science and Technology journal found that LEDs contain lead,
arsenic and a dozen other potentially dangerous substances. However, the life span of LEDs is
37Environmental Science & Technology (ES&T) is an authoritative source of information for professionals in a wide range of
environmental disciplines. The journal combines magazine and research sections and is published both in print and online.
94
approximately 50,000 burning hours and thus the safe disposal of LEDs is not an immediate concern
like conventional lighting.
There exists an e-waste management concept in Indonesia which indicates involvement of retailers,
distributors and local governments for the safe disposal of e-waste. This concept can further be
optimised for the disposal of street lights including LED street lights.
4.7.6.2 Role of Technical Support Unit (TSU)
The TSU should also be involved in capacity building for installation and maintenance of LED street
lighting. The activities which can be performed by TSU are listed below:
Preparation of model tender document for procurement of LED street lights for the cities.
Dissemination of good practices on installation and maintenance to the cities.
Preparation of training modules for different target groups and delivering the training programs.
The TSU can undertake Training of Trainers (ToT) programs, to ensure availability of
appropriately qualified professionals.
4.8. Measurement, Reporting and Verification
4.8.1 MRV of emission reductions
In the context of NAMAs, Measurement, Reporting and Verification (MRV) focuses in particular on the
mitigation outcomes, namely the tonnes of CO2-e reduced. The Conference of the Parties to the
UNFCCC (COP) has defined certain minimum requirements that have to be fulfilled by a NAMA, but
there are many details still to be clarified. MRV of NAMAs can also be used to track co-benefits and
financial streams, especially if donors are involved in the context of a supported NAMA. The following
section describes the main MRV concepts for tracking emission reductions and also outlines potential
additional MRV elements in the NAMA context focusing on sustainable development co-benefits and
financial flows38.
The main objective of an MRV system is to provide credibility for the mitigation action undertaken and
the emissions reductions claimed. It should guarantee environmental integrity and ensure that no
double-counting occurs. Further considerations for a high quality MRV system are transparency, cost-
efficiency, a sound institutional framework and transferability.
4.8.2 NAMA MRV requirements
UNFCCC NAMA MRV requirements currently contain little detail in terms of the specific level of
stringency, data requirements, and degree of external verification. For supported NAMAs at this point in
time the MRV stringency will depend primarily on the requirements of donors, financiers and investors.
38 The development of an actual MRV framework for these parameters is beyond the scope of this report as these are part of a
national process relating to reporting and tracking of finance and NAMA outcomes.
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If the SSLI NAMA is implemented with both unilateral and supported components, then it is likely that
different MRV requirements will have to be taken into account for these different components.
Table 34 below summarises the expected UNFCCC requirements that will be applied to the different
types/elements of NAMAs. Some aspects are still subject to a high level of uncertainty (in particular,
regarding the comments on credited NAMAs, which are not even part of the agreed text at the COP
level).
Table 34: UNFCCC MRV requirements for NAMAs
NAMA type Expected MRV requirements
Unilateral Requirements to be elaborated by Subsidiary Body for Scientific
and Technological Advice (SBSTA) of the UNFCCC
Reflection of national circumstances and priorities expected
Supported Domestic MRV with international oversight
International MRV can be required by donors
Tracking of financial (and technical) support
Credited / financed through
market mechanisms
(unofficial)
Comprehensive MRV requirements
International MRV process
Additionality requirements (?)
The UN rules for biennial reports determine minimum requirements on reporting of NAMAs, which are
summarised in Exhibit 2 below.
Exhibit 2: Information on NAMAs in biennial reports
The UNFCCC Conference of the Parties in Durban 2011 (COP17) agreed on general MRV
requirements without being too specific. The NAMA MRV system may facilitate reporting to
complete the report in a similar format to the biennial update reports especially as this will facilitate
International Consultation and Analysis (ICA). These reports should be done in a tabular format.
Biennial reports should include the following information (UNFCCC, 2011a, Annex III/2):
a) Name and description of the mitigation action, including information on the nature
of the action, coverage (i.e. sectors and gases), quantitative goals and progress
indicators;
b) Information on methodologies and assumptions;
c) Objectives of the action and steps taken or envisaged to achieve that action;
d) Information on the progress of implementation of the mitigation actions and the
underlying steps taken or envisaged, and the results achieved, such as estimated
outcomes (metrics depending on type of action) and estimated emissions
reductions, to the extent possible;
e) Information on international market mechanisms.
96
Where supported NAMAs are concerned, the expectations of providers of climate finance are generally
likely to be that the MRV framework should if possible be based on sound, reliable and approved
standards. Ideally, an approved methodology such as used under the CDM would provide a high level
of confidence. However, from the implementing country point of view, simplification is desirable to
reduce costs and administrative burden wherever possible. Simplification and standardisation is
appropriate since mitigation action for NAMAs is typically to be taken at a sector, or sub-sector level,
rather than at a project level, and the emissions reductions claimed will not be used to offset emissions
reduction obligations (unless NAMA-crediting is intended, which is not considered explicitly as part of
the SSLI NAMA Implementation Plan). The balance appropriate for the MRV of supported NAMAs is
therefore somewhere in between that of the CDM on the one hand, and unilateral action taken purely
by the implementing country on the other. The expanded Table 35 below compares the likely MRV
elements across the three different types of NAMAs, building on concepts that have not yet been defined
by the COP.
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Table 35: Comparison of likely MRV elements for different NAMA types
Characteristics Unilateral NAMA Supported NAMA Credited NAMA
Type of finance To be financed
domestically
To receive international
financial, capacity building
and/or technology support
To receive payment in
return for carbon credits
sold on the market
Stringency and
scrutiny
Lower
Depends on national
standards adopted
Higher
Designed to provide
confidence to financiers
that emissions reductions
claimed are credible
Highest
Designed to provide
confidence to the carbon
markets and ensure
environmental integrity
Programme
oversight
Government department
(e.g. MEMR)
International (bilateral or
multilateral) agreement
between governments
involved, implemented by
matching national
legislation and using
nationally accredited
bodies
International body
implemented on the basis
of an international treaty
and using nationally
accredited bodies
Standards to be
applied
“National standards”
appropriate for Non-
Annex I parties (NAI)
Bilateral standards to be
defined by donor and
recipient
ISO Standard,
internationally recognised
standard such as
approved CDM
methodology
Auditing/
Verification
Defined by implementing
government (could be
internal audit only)
Third party or approved
government body
Third party (similar to
DOE under the CDM)
Transparency
requirements
MRV reports are internal
only, but archived for
possible review
Internal and available to
relevant participants (e.g.
donors) via registry
Publically available
(similar to CDM)
Source: Perspectives own assessment and UNEP Risoe (2012)
4.8.3 Options for the SSLI NAMA MRV framework
The approved CDM methodology AMS-II.L could be used as a starting point for developing the MRV
framework for the SSLI NAMA. The parameters in the CDM methodology should be reviewed and
adapted where appropriate in order for the MRV system to be feasible and appropriate. For instance,
compared with the CDM, monitoring parameters could be adapted to be monitored/reported less
frequently, to be monitored using statistical sampling and/or default values for certain monitoring
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parameters if the CDM methodology does not already allow for this, or with less stringent
reliability/accuracy requirements.
Given the overall SSLI NAMA concept and its nature as a supported NAMA, the MRV system for the
NAMA should focus on the direct GHG emissions reductions, which are estimated by monitoring and/or
estimating the energy savings achieved.
Based on whether cities have full metering in place or not, the following monitoring approaches can be
applied. A combination of the two approaches is also possible, and this is likely to be the most common
approach since most cities have not yet achieved full metering but have already started.
Approach A: Based on the approach in CDM methodology AMS-II.L. Demand-side activities for
efficient outdoor and street lighting technologies
Approach A does not require actual monitoring of consumption using metering.
The approved small-scale CDM methodology AMS-II.L, Demand-side activities for efficient outdoor and
street lighting technologies, defines criteria for MRV that can be used in the NAMA MRV framework.
Most importantly, the monitoring concept relies on theoretical calculations and pre-defined values and
performance standards only. Physical metering of actual consumed electricity is not required, so this
approach can be used even when full metering is not yet installed. The installed lamps have to fulfil
either national or local performance standards or an approved international standard such as CIE’s
Lighting for Roads for Motor and Pedestrian Traffic (CIE 115:2010). The key parameter that is required
to be monitored is operating hours.
The methodology could be utilised to build the NAMA MRV framework, with some elements having the
potential to be simplified, especially in the case that for the ex-ante emission reduction estimation
insufficient data is available. A solution is to have a two-step monitoring approach involving ex-ante
estimation of the impact in terms of emissions reductions (prior to the lighting replacement) and ex-post
verification based on sampling groups (following the lighting replacement). In this way, the emission
reductions are calculated/estimated ex-ante and adjusted/determined ex-post following monitoring,
which is done via surveys using a statistical sampling approach. The basics of this concept are outlined
as follows:
Ex-ante estimation of emission reduction would be built up bottom-up, based on the different baselines
for individual cities to be included in the NAMA, under the modelled implementation scenarios. The key
parameters include the numbers and characteristics of the lamps replaced, the number of
cities/municipalities covered and so on. The estimation of emissions reductions for each city can be
done using the approach derived from the CDM methodology, as outlined in Section 4.6.
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Ex-post MRV will allow for adjustment of the emissions reductions estimated ex-ante. The MRV
undertaken ex-post should be based on a detailed monitoring plan defined by the SSLI TSU (MEMR),
describing all parameters and their use and relevance for the NAMA MRV. The monitoring plan shall
facilitate the process of monitoring and recording of information over the lifetime of the NAMA. The plan
should include details for:
Assumptions/default values used and sources of the values
Sources of monitored parameters
Frequency of monitoring and reporting of monitored parameters
Description of the data storage plan
Responsibilities of different actors involved in monitoring and reporting
Methodologies to be applied to calculate mitigation benefits (including AMS-II.L)
Accuracy level to be applied for sampling
If the recommendation is adopted from Section 4.3.4 that as a pre-condition, each city must have either
at least 50% metering in place, or have conducted a recent audit, this will help contain the potential for
the ex-post results to differ greatly from the ex-ante estimates.
System boundary
It is recommended to use the local electricity distribution network to which street lighting is connected
to define the system boundary(-ies) of the NAMA and the MRV actions to be undertaken. This means
that each city and/or province where the NAMA activities will be implemented represents a sub-system
for the NAMA and MRV shall be performed for each of these sub-systems, considering the physical,
geographical location of all “project” luminaires (lamps) installed – i.e. the efficient lighting technology
replacing conventional lighting as part of the NAMA.
Ensuring lighting performance quality
After implementation and replacement, lighting performance quality of project luminaires shall be
demonstrated as follows:
Equivalence to existing baseline luminaires: prove that project luminaires provide equivalent
or improved total useful illumination (lx), compared to the baseline luminaires being replaced,
at each representative location. Either by: (i) Measurements and calculations; or (ii) Computer
modelling of average illuminance from baseline and project luminaires at representative
locations that shall be determined in accordance with CIE standard 140:2000;4
Compliance with applicable street lighting standard: each city participating in the SSLI
NAMA shall prove that the selected efficient lighting technology/-ies (LED or otherwise) meet
an appropriate standard that is pre-approved by the NAMA TSU within MEMR (see detailed
discussion in Section 4.4).
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Parameters to be monitored
The monitoring activities include:
(a) recording of luminaire distribution data, including the numbers and types of lamps per municipality,
with this data provided by the PJU or potentially by an ESCO if contracted by PJU; and
(b) ex-post monitoring surveys/sampling results. This shall be carried out after installation of all project
luminaires providing a value for the following parameters, with the specific approach taken from AMS-
II.L, and possible to be adjusted for the SSL as appropriate:
Quantity of baseline (BL) or project (P) luminaires of different types distributed and installed
under the NAMA (units). Once all of the project luminaires are distributed or installed, the
quantity is normally a constant value independent from the years, unless the size of operating
luminaire inventory decreases during the monitoring period, in which case only the operating
project luminaires shall be included in the emissions reduction calculation.
Rated power/wattage of the baseline luminaires of the types of lighting devices (kW), or time-
integrated average power if equipment operates at various power settings.
Rated power/Wattage of the luminaires installed as part of the SSLI NAMA for the types of
different lighting devices (kW), or time-integrated average power if equipment operates at
various power settings, normally constant value independent from the year unless operating
schedule or parameters change during crediting period.
Annual operating hours for the baseline and project luminaires in year y. May differ from
baseline scenario to the post-implementation scenario. This value is based on continuous
measurement of daily average usage hours of luminaires for a minimum of 90 days at monitoring
survey sample locations, corrected for seasonal variation of lighting hours and multiplied by 365
days. The method used to extrapolate the 90 days of data to annual values must be
documented. Alternatively, sensors could also be used.
System Outage Factor (SOF) for equipment type. SOF is calculated as the product of the
equipment Outage Factor and the equipment Annual Failure Rate. The value for the baseline
is assumed to be the same as monitored post-implementation and may vary from year to year.
The grid emission factor (GEF) is calculated by MEMR for the various electricity grids in Indonesia and
regularly updated (see Section 4.3.3).
From the above, it is clear that the key parameter from a measurement point of view is the average
annual operating hours. For this, a simple recorder of on/off time or direct monitoring over time of power,
or even light intensity, may be used. It is the only parameter that needs to be physically measured, and
this can be done using sampling.
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For each ex-post monitoring survey, the CDM methodology AMS-II.L requires that the monitoring shall
include continuous monitoring of equipment run-time for at least 90 continuous days to determine
average daily operating hours for extrapolation to annual operating hours (O i). It is suggested that this
requirement could be made more flexible in the context of the SSLI NAMA.
Frequency
Subsequent ex-post monitoring surveys should be carried out at least every second year after the first
year of the period in which emissions reductions are monitored (i.e. years 3, 5, 7, 9).
Sampling
Due to the high number of lamps that would be replaced in each city under the SSLI NAMA it is not
possible to directly monitor the energy consumption of each lamp, unless meters which allow this are
installed. From discussions with city PJUs it is understood that the preferred technology options typically
cover up to 25 lamps per metering unit. This would provide a relatively high level of accuracy for the
energy consumption of installed lamps, provided that other factors such as losses due to deterioration
of ballasts, sub-optimal cabling and theft are accounted for in the metered data. If the PJU also invests
in optimisation of these factors at the same time as installing the LEDs or other efficient lamps then the
metering data from each metering point can be used and split between the different lamps installed.
While installation of metering is a high priority from a municipal budget point of view, it is not
recommended to require that all cities participating in the NAMA have reached full metering as a pre-
condition. Some cities may wish to join while they are still implementing their metering roll-out. Requiring
full metering prior to joining would significantly increase the up-front capital costs of the NAMA
implementation and delay achievement of emissions reductions.
Therefore, a sampling approach should be an available option for determining the achieved emission
reductions. CDM methodology AMS-II.L suggests calculating the sample size for each sampling group
to achieve a minimum 90% confidence interval and 10% maximum error margin. The sampling size then
depends on the expected mean value and the standard deviation of a specific parameter (e.g. operating
hours). The CDM “Standard for sampling and surveys for CDM project activities and programme of
activities” defines also minimum requirements for sampling, which can be used as a guide for defining
the SSLI NAMA sampling plan. For small scale (SSC) activities a level of confidence/precision of
90%/10% respectively is required, while for large scale activities a level of confidence/precision of
95%/10% is required39. As an illustrative example, the likely scale for the Demonstration Phase of the
SSLI NAMA is between 4.75 and 15.2 GWh of energy savings per annum, depending on whether it
includes 2 or 4 cities. This suggests, on average, energy savings of less than 4 GWh pa per city, which
is well below the CDM small scale threshold of 60 GWh pa. It is suggested, therefore, that the more
39 According the CDM Project Standard (EB 65, Annex 5) the small scale threshold for Type II project activities is defined as:
Energy efficiency improvement project activities that reduce energy consumption, on the supply and/or demand side, with a
maximum output of 60 GWh per year (or an appropriate equivalent) in any year of the crediting period.
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relaxed confidence/precision levels from the sampling rules for SSC CDM activities are appropriate to
be applied for cities involved in the SSLI NAMA.
Even if we were to assume the more stringent confidence/precision requirements, as can be seen in
Table 36 below, the minimum sample size would be just 24 lamps by city/province (sub-system to reach
a 10% precision and keep a 95% confidence interval. As a general principle (rule of thumb), however, it
is recommended to have a sample size of at least 30 lamps per sub-system to ensure reliability of the
sampling result40.
This initial analysis thus suggests a very manageable sampling requirement under the SSLI NAMA in
terms of costs and human resources for each city.
Table 36: Minimum sample size in dependency of the confidence interval
Sample assumptions
Precision 0.1
Total no. of lamps 10,000
Range of
parameter
0.5
Estimation of sample size
Operating hours
(h/d)
Standard
Deviation
V Sample size
(0.95; 1.96)
Sample size
(0.9; 1.645)
10 2.5 0.06 24 17
Approach B: Use individual meters and eventually smart control systems.
This approach is ultimately required from the point of view of optimising the street lighting systems
across Indonesian cities and provinces. Without installation of metering, cities are unable to shift away
from the lump-sum billing system and will find it difficult to clarify the reasons for non-technical losses
that are estimated to be up to 40% based on the experience in Yogyakarta for example.
Metering technology would have to be installed such that it is possible to meter the actual consumption
of lamps, not just sections of a street with multiple poles, since theft could still be an issue in the case
of the latter. If metering data cannot be attributed directly to the connected lamps for each metering unit
then the volume lost due to theft could still appear in the metered data. One advantage of the CDM
approach is that it avoids this issue. If the configuration of metering technology does not take this issue
40 According to the Standard for Sampling and Surveys for CDM Project Activities and Programmes of Activities, if the sample
size calculation returns a value of less than 30 samples, a minimum sample size of 30 shall be chosen when the parameter of
interest is a proportion. If the parameter of interest is a numeric mean value the Student’s t-distribution shall be used. Thus in the
case of lamp operating hours, this would apply, since it is not a proportion or percentage, but rather a mean value.
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into consideration, then some other solution is required – e.g. at the time of meter installation all illegal
connections need to be either removed or brought into the “legal” system (metered and billed
accordingly). Regular audits/surveys can also be applied after metering has been installed, to check
whether new illegal connections have been installed.
The actual reading and calibration will be done by PLN. Hence, for the measurement of energy
consumption for the NAMA MRV, the metering data needs to be provided by PLN to the corresponding
PJU and then verified and fed into the NAMA MRV system which will be maintained by the TSU in
MEMR.
4.8.4 MRV of co-benefits
Apart from emission reduction, the SSLI NAMA results in co-benefits such as sustainable development
benefits to the economy, environment and population. In particular, there is likely to be an improvement
in safety standards in urban areas, and possibly a reduction in traffic accidents. It is recommended to
also track these indicators as part of the MRV framework. Where possible, this should be referenced
against existing data that might exist in individual municipalities and provinces or even on a national
level. When developing the evaluation framework for co-benefits, particularly for sustainable
development benefits, it may be useful to refer to the CDM sustainable development checklist of the
Designated National Authority (DNA), if available, and taking into account national circumstances.
Potential criteria and measurable indicators for co-benefits for the SSLI NAMA are included in the Table
37 below.
Table 37: Criteria and measurable indicators for co-benefits
Criteria Indicator
Economic
Job creation - Created employment - Availability of qualified, highly efficient productive national
labour
Energy security - More efficient use of fossil fuels - Reduced import rates of fossil fuels - Reduced costs
Reduced road accidents - Cost savings - Saved lives
Social
Enhancement of quality of life
- Health improvements (safety, fewer accidents, violent crimes) - Distribution of costs and benefits - Income distribution - Local participation in civic life - Enhancement of health conditions and safety standards
Environmental
Reduction of local/regional environmental impacts
- Reduction in other pollutants (e.g. from Mercury lamps)
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4.8.5 Institutional responsibilities for MRV
The overall responsibility for the development, implementation and running of the MRV system, including
data collection, calculation and storage is recommended to be with the SSLI TSU within MEMR. The
TSU would be responsible for the development and running of an electronic database to record and
manage all relevant baseline and monitoring information. This database will include, inter alia,
identification data and numbers of lamps covered under the NAMA (Identification Records), which will
allow, in case no meters are installed, calculating the corresponding adjustment of the emission
reduction calculation ex-post based on Monitoring Records (operating hours, wattage) as outlined
above. The database will also help avoid potential double counting of emission reductions (e.g. between
provincial level streets and municipal level streets). PJUs will be responsible for both the implementation
of the lamp replacement, provision of metered data to the TSU and conducting the field measurements
(based on sampling for determining the operating hours). If the electricity bills received from PLN do not
provide PJUs with metered data broken down to a sufficient level of detail – that is, meter by meter –
then it will be necessary to obtain actual metering data. The TSU may need to facilitate between PLN
and the PJUs if this data is not readily provided by PLN.
Figure 21 shows the proposed institutional responsibilities for the MRV framework and the data flows
that are needed to track the overall performance of the SSLI NAMA.
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Figure 21: Institutional set-up for MRV
The SSLI TSU’s technical unit will provide technical support on the installation, maintenance and MRV
to PJUs that will in turn supply data that are required for the emission reduction calculation and reporting
of the overall NAMA performance. The
Table 38 below identifies the data to be obtained for estimating parameter values and the responsibilities
for obtaining these, as well as the method.
Table 38: Method for obtaining parameter values under MRV framework
Parameter Responsibility Method
Number of lamps PJU Maintain records
Type of lamps PJU Supplier specifications
Wattage of lamp PJU Supplier specifications
Operating hours of lamps
(for the case of lamps which are
not yet metered)
PJU Via sampling
Electricity consumption data
(for the case of lamps which are
metered)
PJU Obtained from PLN
MEMR
SSLI TSU
Technical unit
Replaced / installed efficient street lightning in municipalities
NAMA Monitoring Database
PJUs PLNPrivate sector
(ESCOs / suppliers)Installing, reading andcalibration of meters
Replacing lampsMeasuring
Replacing lampsMeasuring
Auditors
Potential verification of data through sampling
Data: • Metered electricity consumption• Monitoring data (e.g. no. lamps, operating hours)
Training reflecting NAMA MRV requirements
Certification of auditors
Technical support on installation, maintenance and MRV
Metered electricity(if meters are installed)
Number of lamps, type, wattageOperating hours (if no meters exist)
Implementing replacement
BAPPENAS
Reporting of overall performance
Preparation of monitoring
reports
Carrying out tasks,if assigned by PJU
Electricityconsumption/ bill
Verification of data received by ESCOs and / or verification of monitoring reports
Data flow
TA / implementation
Optional
UNFCCC / NAMA Registry
Donors / investors
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The implementation of the replacement and the monitoring could also optionally be outsourced on a
commercial basis – i.e. be conducted by private companies such as an ESCO or energy auditor,
depending on the individual situation of the municipalities and the PJU. In the Figure above it is indicated
as an option, with dotted lines. The same is true for a potential verification of data by a third party auditor.
The auditors could provide their assessment at basically two steps of the data flow. First, PJUs may
have the interest to obtain a verification of the performance and data received by contracted ESCOs for
commercial reasons. Secondly, the monitoring report that will be prepared by the TSU would be
externally verified, before it is submitted as part of the national MRV process, i.e. submitted to
BAPPENAS. In general, it is suggested to align the SSLI NAMA reporting to the national reporting (RAD-
DAK) system (see approach in EU MRV CB/GIZ PAKLIM, 2012). Some form of international
audit/oversight may also be required as part of the supported NAMA component where international
finance is provided.
To produce monitoring / performance reports of the NAMA the TSU will run a NAMA database (e.g.
Excel based). The database will capture both Identification records (once when the replacement of
lamps takes place) and the Monitoring records (annually / biennially depending on data availability /
methodology of data sourcing, e.g. with or without meters). Additionally, specific monitoring information,
e.g. the GEF, and information of financial flow as well as potentially co-benefits should be included.
Figure 22 below summarises the data included and the general process for the preparation of the NAMA
reports based on the data base.
Figure 22: NAMA database for MRV
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4.8.6 MRV of financial flows
Tracking the financial flow could be aligned to the institutional set-up for the MRV as outlined above. As
the main two receivers of financial funds will be PJUs and/or private actors (ESCOs) they will need to
report back to the providers of those funds - either the ICCTF (BAPPENAS) or the PIP. The TSU should
also receive the information and provide an overall financial report that can be submitted to
donors/investors, , as well as used for domestically purposes, as outlined in the Figure 23 below.
Figure 23: Tracking of financial flows under the NAMA
4.8.7 Recommendations
The MRV framework for the SSLI NAMA can be based on a combination of the two options outlined
above – using metered data wherever available and using the approach outlined in the approved CDM
methodology AMS-II.L where metered data is not available for installed lamps. We see some scope for
simplification and adaptation to suit the particular circumstances of each city involved in the NAMA. The
CDM approach does not require actual measurement of electricity consumption, but instead uses
sampling of operating hours and calculated energy savings. Cities that are already advanced with their
metering installation programme and can accurately measure electricity consumption should, however,
utilise metered data for emissions monitoring under the NAMA.
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4.9. Raising awareness amongst stakeholders
This chapter identifies the current level of awareness amongst all stakeholders on the usage of energy-
efficient street lighting technologies. An assessment of the uptake of these technologies in cities (target
group), prevalent mechanisms facilitating such an uptake and an identification of the capacities of
agencies supporting this process is presented here. Based on this assessment, specific needs for
capacity building and raising awareness are identified.
4.9.1 Background
Implementation of energy efficient street lighting technologies in cities has been identified as a high
impact energy efficiency measure which can contribute to Indonesia’s stated target of reducing
emissions. However, the applicability of these technologies, required policy frameworks for facilitating
their adoption, knowledge of appropriate design specifications and on-ground implementation
requirements are not widely known amongst all stakeholders, including agencies responsible for the
implementation of Indonesia’s targets under the NAMA framework, local authorities and citizens. Select
advanced cities are aware of related technological options and their cost – benefit implications. Adoption
of these technologies is also hindered by certain financial and economic barriers, technological barriers
(related to inappropriate design and sub-standard material), institutional and organizational barriers and
identified behavioural barriers. Table 39 below summarises these barriers usually associated with
uptake of energy efficiency measures and policies:
Table 39: Barriers associated with uptake of energy efficiency measures and policies
Barrier type Specific issues
Financial and economic barriers Energy prices, inefficient energy subsidies and price volatility
Market structure and functioning
Financial incentives
Lack of funding (private and public funds)
Costs (e.g. high upfront costs)
Technological barriers Non-availability of requisite standard of material
Lack of technical standards
Behavioural barriers Social, cultural, and behavioural norms and aspirations
Decision-making problems (e.g. split incentives)
Institutional, information and
organizational barriers
Lack of awareness, information, education and training
Policies detrimental to energy-efficiency
Lack of legal and regulatory frameworks
Limited institutional capacity
Lack of coordination and slackness
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Stakeholders comprising government agencies, NGOs, street lighting equipment manufacturers, and
others with an interest in promoting effective, energy-efficient lighting throughout the country can help
in executing a broad roadmap to implement energy efficient lighting technologies in Indonesia.
4.9.2 Awareness & Capacity Building Need Assessment
Many cities in Indonesia are not aware of the various LED street lighting technologies and the benefits
associated with it. In addition, absence of national standards on LED street lighting, lack of testing
facilities, manufacturers, suppliers and installers, all result in preventing an active and quick uptake of
EE street lighting technology in cities. In light of the above mentioned issues, awareness raising activities
for promoting LED street lighting technologies should be planned and executed in a holistic manner,
addressing all relevant stakeholders, including policy and decision makers, market actors and
influencers, consumers and end users of the technology. An assessment of the current capacities of all
involved institutions to support and promote uptake of LED technologies was carried out and measures
are identified to further strengthen their roles.
4.9.2.1 Standards on LED street lighting
The absence of national standards on LED Street lighting is a major impediment for active technology
roll out in the country. Discussions with relevant ministries involved in setting standards indicate that
they are facing several challenges to come up with a national standard on LED street lighting. Such a
standard will guide consumers in selecting the best available technology, based on scientific design
guidelines, and will also curtail sub-standard products in the market. Cities will be empowered to take
appropriate, beneficial decisions, considering long term financial sustainability and emission mitigation
potentials.
4.9.2.2 Manufacturers, suppliers, installers of technology
There is a need for promoting local manufacturers producing high quality equipment. The supply chain
and servicing industry for these products has to be strengthened. In the absence of good in house
production capability, substandard products are sold in the market; poor performance of these products
impacts the assessment of this technology.
4.9.2.3 Financial Models
Cities need to be supported by appropriate financial mechanisms to be able to absorb the upfront costs
of adopting this technology, which are relatively higher than implementing conventional street lighting
technologies. As discussed in the Financing section, a range of domestic and international financing
mechanisms can be used to support cities to adopt these technologies. Awareness raising efforts will
be needed to encourage cities to take advantage of the available financing mechanisms.
4.9.2.4 Enabling Policies
Framework conditions should be established to facilitate adoption of private sector approaches like
greater use of the ESCO model. This has been elaborated in Section 4.5 (Financing options for efficient
street lighting) of this report. Currently, policies are not in place, which enable ESCOs to participate in
energy efficiency contracts with cities.
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4.9.3 Designing of Awareness & Capacity building Strategies
Cities are the ultimate decision makers in terms of selection of a particular technology for street lighting
operations. Several external and internal factors impact these decisions. A range of awareness raising
activities addressing different groups of stakeholders can be undertaken across the country to address
these issues:
Awareness raising seminars, trainings and campaigns for all stakeholder groups including policy
makers, manufacturers, suppliers, installers, end users and the community at large. By
educating the community on the benefits of LED based street lighting (energy savings,
environmental safe end of life disposal, low impact on urban sky glow); a positive demand for
this technology is created, despite apprehensions of high upfront capital costs.
Short term, medium term and long term education courses at the university level to create
practicing professionals who can support the adoption and implementation of this technology;
Showcasing of selected cities chosen in the demonstration phase to demonstrate the LED
technology and monitor performance;
Development of national guidelines on recommended practices, and model efficiency programs
related to LED street lighting; and
The continual dissemination of new information to stakeholders throughout the country through
a focused and concerted programme implemented through an identified department/ministry.
Such a programme should be backed by appropriate financial, regulatory and monitoring
frameworks to facilitate LED street lighting.
4.9.3.1 Training programs, seminars and campaigns:
There is a need to create a series of training programs, seminars and campaigns for different target
groups in Indonesia to tap various benefits associated with LED street lighting technology. Based on
discussions with all concerned stakeholders, these programs should clearly outline solutions for
mitigating identified barriers for LED technology uptake; the TSU should take a lead in developing these
programs and should coordinate with other concerned ministries to implement these programs,
seminars and campaigns. These programs should be targeted at the below mentioned stakeholder
groups:
Policy makers and government officials
Manufacturers at the national level
Suppliers and installers
Investors and financiers
Academic and research institutions
NGOs
Cities and local authorities
Local community groups and citizens
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Table 40: Target groups for training and focus areas
Target Group Focus Areas
Policy makers and government
officials
Information on benefits of energy efficient lighting
systems
Model programs and policies that have helped in energy
savings in other countries.
National forums, seminars and workshops could be the
best medium of information dissemination for this group.
Manufacturers at the national
level
Information to generate awareness on opportunities that
lie in energy efficient lighting systems
Developing requisite expertise so as to enable local
manufacturers to develop facilities and supply related
material and equipment
Seminars, training programs etc. could be targeted to
engineers and technicians in these companies, focusing
on relevant standards for equipment.
Suppliers and installers Training on benefits of using energy efficient lighting
system from the user’s perspective.
Information on requisite specifications and standards of
these products in order to ensure supply of
material/equipment of desired quality.
Short term training programs, interaction with
manufacturers etc. could be of benefit.
Investors and financiers Information on investment opportunities in this area.
Successful financial models can be discussed with them.
Short webinars with the target group can help in
achieving the desired results.
Academic and research
Institutions
Information on new research and development in this
sector in other parts of the world.
In depth training to all stakeholders with regard to the
latest technology with the help of identified experts can
be of use.
NGOs Short term training programs to spread awareness on
benefits of using energy efficient lighting.
Cities and Local Authorities Information on available energy efficient technologies
and benefits associated with it.
Information on manufacturers and suppliers of related
material/equipment meeting international/stipulated
national standards in local markets
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Information on a complete model, including appropriate
technology, policy framework, financing and operation &
maintenance of such systems, enabling decision making
in local authorities on related aspects.
Local Community Groups and
citizens
General information on energy efficiency technologies
and linking it with the larger picture of energy security.
Their role in creating a demand for energy efficient
lighting can be discussed during such training programs
Addressing barriers to acceptance of new energy efficient
lighting technologies and apprehensions associated with
their uptake
4.9.3.2 Graduate and University level courses:
Colleges and universities can help play a big role in creating awareness on efficient technologies
including LED street lighting in Indonesia. Certain education programs, short / medium / long term
courses on energy efficiency technologies can be introduced so as to prepare future professionals to
implement efficient lighting technologies. Professors at the university with expertise in related fields can
be part of training programs to educate all the stakeholders. Further universities and colleges in urban
areas can be utilised to demonstrate pilot projects of LED street lighting. These institutions may be
identified as preferential locations for conducting training programmes for the community. MEMR and
technical support unit (TSU) can work with ministry of education and human resources to carry forward
these activities.
4.9.3.3 Implementation of pilot and demonstration projects:
The LED street lighting technology is still at a nascent stage in Indonesia and particularly the cities are
not ready to adopt the technology on wider scale. The apprehensions related with experimenting with a
new technology increases when there are high upfront cost associated with it. In such scenarios, the
implementation of pilot projects at strategic locations in selected cities can help in a great way to resolve
the problem. The city of Malang with support from GIZ and OSRAM has implemented one such pilot
project on one of the prime roads in the city.
The proposed approach is that the cities chosen for the demonstration phase of the SSLI NAMA can be
used to showcase the benefits of LED technology to other cities. Subsequently, more cities will join the
NAMA during the scaling up phase, and the results of this will be used to spread further uptake during
the transformation phase.
4.9.3.4 Continuous dissemination of information amongst stakeholders:
All identified stakeholders should be continually informed of newly emerging and available LED
technologies, relevant to the local Indonesian context. The advantages of adopting these technologies
in cities should be constantly emphasised. Information dissemination should use multi-media channels
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effectively to address all sections of stakeholders – creating effective info graphics for use in public
media, messages disseminated through appropriate online social network channels, targeted school
programs, community level dissemination through public broadcasting using information leaflets and
other dissemination material. One of the tasks of the TSU could be the design and implementation of a
planned information dissemination programme in all cities, using various media solutions.
4.9.3.5 Role of the Technical Support Unit (TSU):
The TSU could coordinate all awareness building activities to support implementation of LED street
lighting in Indonesia. The activities proposed for TSU under awareness and capacity building is:
Planning and roll out of the awareness building initiatives under SSLI NAMA.
Coordination, monitoring and evaluation of the on-going awareness building activities related to
LED streetlight implementation in other divisions of the Ministry.
Develop and maintain a database of local governments - human resources – staff & elected
representatives and training infrastructure facilities in the area of energy efficiency at local and
provincial level.
Develop and maintain an inventory of training/research institutes working in energy efficiency
sector in Indonesia.
Establish and operate an E-library.
Advise MEMR on new themes requiring awareness building activities.
Undertake research studies on LED street lighting and publication of reports.
Any other activities related to capacity building as directed by MEMR.
5. Summary of recommendations
Institutional set-up
1. A Technical Support Unit (TSU) within MEMR should be established to facilitate the implementation
of the NAMA, and coordinate the activities of all of the involved agencies. Part of the international
grant funding component should be used for these activities.
Policy and regulations
2. MEMR envisages to consult with PLN on a transparent procedure for the calculation of consumption
of electricity from efficient street lighting. This would help reduce transaction costs and increase the
incentive for PJUs to invest in more efficient lighting. Two tracks are recommended – one with and
one without metering.
3. MEMR envisages to facilitate a more rapid move to full metering of street lighting in Indonesian cities
by offering facilitation and/or financial support. This would help incentivise cities to switch to more
efficient lighting technologies and ensure the SSL NAMA is implemented more successfully.
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Baseline data
4. It is recommended to further explore the reasons for discrepancies between reported energy
sales/national street lighting consumption statistics and actual electricity consumption, so that an
accurate emissions baseline can be established.
5. In the meantime, it is recommended to impose a requirement on cities wishing to join the SSLI
NAMA that they have at least one of the following:
a) The city has metering in place to cover a minimum percentage of street lighting load (e.g. above
50%); or
b) The city has conducted an audit within a minimum timeframe (e.g. within the last 3 years prior to
joining the NAMA).
6. It is also recommended that the baseline for individual cities/municipalities joining the SSLI NAMA
in the demonstration phase should be established on a city-by-city basis using the following
approaches:
a) For cities where full coverage metering has already been installed or is soon to be installed, it is
recommended to use the metered data for baseline establishment.
b) For the non-metered component of the consumption (up to 50%), use the calculated approach
as outlined in this section and in Section 4.6.2 (where the emissions reduction equations are
included based on approved CDM methodology AMS-II.L).
c) When applying option b), emissions reductions calculated ex-ante should be verified ex-post
during the monitoring phase, as is outlined in Section 4.7.
Performance and safety standards
7. Consensus is required from the relevant ministries including MEMR, MoI, MPW and MoT together
with BSN to adopt the existing international standards (including IEC and IES standards) or
standards from similar Asian countries, such as India. TSU is recommended to provide technical
support to relevant ministries for setting LED standards.
8. SNI 4 6973.2.3-2005 (Part 2.3 of Lamps: Special requirements of street lighting). This standard
specifies the luminaire standard for other lamps. LED could be added as addendum to this standard.
9. Directorate General of Bina Marga (Highway) could request Puslitbang to review the existing safety
and performance standards and add specific standards for LED street lighting.
10. A detailed technical specification document (bid document) on LED street lighting procurement for
all kinds of roads could be developed by BSN.
11. Testing protocols, infrastructure and accredited laboratories must be set up to ensure testing of
LEDs for compliance to the technical standards.
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12. Name of suppliers/manufacturers complying with national standards are to be listed in government
websites for the reference of users
13. Due to non-availability of national LED standards other smart street lights such as induction lamps
could also be considered under NAMA
Financing options
14. Utilise international NAMA support in combination with domestic finance sources to kick-start the
SSLI NAMA Implementation. International NAMA support funding provided by a grant from the
NAMA Facility or similar could provide a grant in the order of 11.5m USD to be administered via the
ICCTF. This should be used for SSLI lighting replacement investment in 2-4 targeted cities in the
demonstration phase from early 2014 – mid 2015.
15. An additional 6-8m USD funding should be sought for technical assistance, specifically for the set-
up and operation of the TSU to support local governments in accessing domestic finance via the
ICCTF, loans from PIP and potentially other sources.
16. As a priority, the national government should enable local government to enter into contractual
arrangements with ESCOs by reforming the regulatory framework.
17. TSU should work with PIP to smooth the process for entering into soft loan arrangements with
municipal and provincial governments. Consider using PIP loans to help cities enter into ESCO
arrangements.
18. In the scaling-up phase, from mid 2015-end 2016, aim for a further 2-8 cities joining the SSLI NAMA,
supported primarily via PIP loans and ESCO financing. In the transformation phase, from early 2017
to end 2019, aim for further 5-10 cities joining the SSLI NAMA, supported by PIP loans, ESCO
financing to the extent possible. Once exhausted, either commercial loans or new sources of finance
will be required.
19. Under the ambitious scenario without new sources of donor finance or national government financial
incentives (e.g. DAK grants or a dedicated loans facility for energy efficiency), the NPV will be
negative in 2024. In order to present an economically attractive option for the municipalities,
additional sources of NAMA finance would be required. For example, a second grant of 11.5m USD
during the transformation phase would generate a positive NPV. International donors but also
national, public institutions should be approached for financing.
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Installation and Maintenance
20. The national standards and guidelines on installation and maintenance need to be enforced upon
at the local level by national government. Besides this, the existing standards are to be
supplemented with additional standards on LED streetlights.
21. There is a great need for developing training and capacity building programs for the target groups
so as to enable them to better execute installation and maintenance within the city area.
MRV
22. The MRV framework for the SSLI NAMA can be based on a combination of two options: 1) using
metered data wherever available covering the installed lamps; and 2) using the approach outlined
in the approved CDM methodology AMS-II.L where metered data is not available for installed lamps.
Cities should utilise metered data for emissions monitoring under the NAMA to the extent possible
given the level of metering.
Raising awareness
23. The awareness raising activities for a larger uptake of LED streetlights by city governments will need
holistic efforts from different level of stakeholders starting from the national, provincial and also at
the local government level. The activities listed out in the above mentioned section can be
implemented in a phased wise manner after prioritising the activities which need to immediately take
off. Seminars, training programs and campaigns have a wider role to play in engaging the different
level of stakeholders in identifying the barriers and coming up with logical solutions for the
technology to widespread in the country.
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Annexure 1 - IEC Published LED standards
A) Lamps
1) IEC 62031 LED Modules for General Lighting – Safety Specifications
2) IEC / TS 62504 General Lighting – LED’s and LED Modules, Terms & Definitions
3) IEC 62560 Self-ballasted LED Lamps for GLS > 50V, Safety Specifications
4) IEC 62612 Self-ballasted LED Lamps for GLS >50V, Performance Requirements
5) IEC / PAS 62707-1 LED Binning – Part 1 General Requirements and White Grid
6) IEC / PAS 62717 LED Modules for General Lighting – Performance Specifications
B) Caps & holders
1) IEC 60838-2-2 Miscellaneous Lampholders - Part 2-2 Particular Requirements-
connectors for LED Modules
C) Auxiliaries for Lamps
1) IEC 61347-2-13, Lamps Control Gear Part 2-13: Particular Requirements for dc or ac
supplied Control Gear for LED Modules
2) IEC 62384 DC or AC Supplied Electronic Gear for LED Modules- Performance Requirements
3) IEC 62386-207 Digital Addressable Lighting Interface Part 207: Particular Requirements for
Control Gear - LED Modules (device type 6)
D) Luminaires
1) IEC /PAS 62722-2-1 Luminaire Performance Part 2-1: Particular Requirements for LED
Luminaire.
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